2000 character limit reached
Physics-Informed Neural Network for Volumetric Sound field Reconstruction of Speech Signals
Published 14 Mar 2024 in eess.AS | (2403.09524v2)
Abstract: Recent developments in acoustic signal processing have seen the integration of deep learning methodologies, alongside the continued prominence of classical wave expansion-based approaches, particularly in sound field reconstruction. Physics-Informed Neural Networks (PINNs) have emerged as a novel framework, bridging the gap between data-driven and model-based techniques for addressing physical phenomena governed by partial differential equations. This paper introduces a PINN-based approach for the recovery of arbitrary volumetric acoustic fields. The network incorporates the wave equation to impose a regularization on signal reconstruction in the time domain. This methodology enables the network to learn the underlying physics of sound propagation and allows for the complete characterization of the sound field based on a limited set of observations. The proposed method's efficacy is validated through experiments involving speech signals in a real-world environment, considering varying numbers of available measurements. Moreover, a comparative analysis is undertaken against state-of-the-art frequency-domain and time-domain reconstruction methods from existing literature, highlighting the increased accuracy across the various measurement configurations.
- Tohyama, M., Koike, T., Bartram, J.F.: Fundamentals of acoustic signal processing. Acoustical Society of America (2000) Pezzoli et al. [2021] Pezzoli, M., Carabias-Orti, J.J., Cobos, M., Antonacci, F., Sarti, A.: Ray-space-based multichannel nonnegative matrix factorization for audio source separation. IEEE Signal Processing Letters 28, 369–373 (2021) Cobos et al. [2017] Cobos, M., Antonacci, F., Alexandridis, A., Mouchtaris, A., Lee, B., et al.: A survey of sound source localization methods in wireless acoustic sensor networks. Wireless Communications and Mobile Computing 2017 (2017) Koyama and Daudet [2019] Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Carabias-Orti, J.J., Cobos, M., Antonacci, F., Sarti, A.: Ray-space-based multichannel nonnegative matrix factorization for audio source separation. IEEE Signal Processing Letters 28, 369–373 (2021) Cobos et al. [2017] Cobos, M., Antonacci, F., Alexandridis, A., Mouchtaris, A., Lee, B., et al.: A survey of sound source localization methods in wireless acoustic sensor networks. Wireless Communications and Mobile Computing 2017 (2017) Koyama and Daudet [2019] Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Cobos, M., Antonacci, F., Alexandridis, A., Mouchtaris, A., Lee, B., et al.: A survey of sound source localization methods in wireless acoustic sensor networks. Wireless Communications and Mobile Computing 2017 (2017) Koyama and Daudet [2019] Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pezzoli, M., Carabias-Orti, J.J., Cobos, M., Antonacci, F., Sarti, A.: Ray-space-based multichannel nonnegative matrix factorization for audio source separation. IEEE Signal Processing Letters 28, 369–373 (2021) Cobos et al. [2017] Cobos, M., Antonacci, F., Alexandridis, A., Mouchtaris, A., Lee, B., et al.: A survey of sound source localization methods in wireless acoustic sensor networks. Wireless Communications and Mobile Computing 2017 (2017) Koyama and Daudet [2019] Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Cobos, M., Antonacci, F., Alexandridis, A., Mouchtaris, A., Lee, B., et al.: A survey of sound source localization methods in wireless acoustic sensor networks. Wireless Communications and Mobile Computing 2017 (2017) Koyama and Daudet [2019] Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Cobos, M., Antonacci, F., Alexandridis, A., Mouchtaris, A., Lee, B., et al.: A survey of sound source localization methods in wireless acoustic sensor networks. Wireless Communications and Mobile Computing 2017 (2017) Koyama and Daudet [2019] Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Koyama, S., Daudet, L.: Sparse representation of a spatial sound field in a reverberant environment. IEEE Journal of Selected Topics in Signal Processing 13(1), 172–184 (2019) Ueno et al. [2018] Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Ueno, N., Koyama, S., Saruwatari, H.: Kernel ridge regression with constraint of helmholtz equation for sound field interpolation. In: 2018 16th International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–440 (2018). IEEE Ueno et al. [2017] Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Ueno, N., Koyama, S., Saruwatari, H.: Sound field recording using distributed microphones based on harmonic analysis of infinite order. IEEE Signal Processing Letters 25(1), 135–139 (2017) Pezzoli et al. [2022] Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pezzoli, M., Cobos, M., Antonacci, F., Sarti, A.: Sparsity-based sound field separation in the spherical harmonics domain. In: ICASSP 2022-2022 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1051–1055 (2022). IEEE Pezzoli et al. [2018] Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pezzoli, M., Borra, F., Antonacci, F., Sarti, A., Tubaro, S.: Reconstruction of the virtual microphone signal based on the distributed ray space transform. In: 2018 26th European Signal Processing Conference (EUSIPCO), pp. 1537–1541 (2018). IEEE Pulkki et al. [2018] Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pulkki, V., Delikaris-Manias, S., Politis, A.: Parametric Time-frequency Domain Spatial Audio. Wiley Online Library, ??? (2018) Del Galdo et al. [2011] Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Del Galdo, G., Thiergart, O., Weller, T., Habets, E.: Generating virtual microphone signals using geometrical information gathered by distributed arrays. In: 2011 Joint Workshop on Hands-free Speech Communication and Microphone Arrays, pp. 185–190 (2011). IEEE Lluis et al. [2020] Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Lluis, F., Martinez-Nuevo, P., Bo Møller, M., Ewan Shepstone, S.: Sound field reconstruction in rooms: Inpainting meets super-resolution. The Journal of the Acoustical Society of America 148(2), 649–659 (2020) Kristoffersen et al. [2021] Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Kristoffersen, M.S., Møller, M.B., MartÃnez-Nuevo, P., Østergaard, J.: Deep sound field reconstruction in real rooms: Introducing the isobel sound field dataset. arXiv preprint arXiv:2102.06455 (2021) Pezzoli et al. [2022] Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pezzoli, M., Perini, D., Bernardini, A., Borra, F., Antonacci, F., Sarti, A.: Deep prior approach for room impulse response reconstruction. Sensors 22(7), 2710 (2022) Donoho [2006] Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Donoho, D.L.: Compressed sensing. IEEE Transactions on information theory 52(4), 1289–1306 (2006) Lee [2017] Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Lee, S.: The use of equivalent source method in computational acoustics. Journal of Computational Acoustics 25(01), 1630001 (2017) Antonello et al. [2017] Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Antonello, N., De Sena, E., Moonen, M., Naylor, P.A., Van Waterschoot, T.: Room impulse response interpolation using a sparse spatio-temporal representation of the sound field. IEEE/ACM Transactions on Audio, Speech, and Language Processing 25(10), 1929–1941 (2017) Caviedes-Nozal and Fernandez-Grande [2023] Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Caviedes-Nozal, D., Fernandez-Grande, E.: Spatio-temporal bayesian regression for room impulse response reconstruction with spherical waves. IEEE/ACM Transactions on Audio, Speech, and Language Processing (2023) Hahmann et al. [2021] Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Hahmann, M., Verburg, S.A., Fernandez-Grande, E.: Spatial reconstruction of sound fields using local and data-driven functions. The Journal of the Acoustical Society of America 150(6), 4417–4428 (2021) Vovk [2013] Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Vovk, V.: Kernel ridge regression. In: Empirical Inference: Festschrift in Honor of Vladimir N. Vapnik, pp. 105–116. Springer, ??? (2013) Durán and Grande [2023] Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Durán, A.A.F., Grande, E.F.: Room impulse response reconstruction from distributed microphone arrays using kernel ridge regression. In: 10th Convention of the European Acoustics Association (2023). European Acoustics Association Ribeiro et al. [2022] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Region-to-region kernel interpolation of acoustic transfer functions constrained by physical properties. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2944–2954 (2022) Ribeiro et al. [2020] Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Ribeiro, J.G., Ueno, N., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer function between regions considering reciprocity. In: 2020 IEEE 11th Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5 (2020). IEEE Ribeiro et al. [2023] Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Ribeiro, J.G., Koyama, S., Saruwatari, H.: Kernel interpolation of acoustic transfer functions with adaptive kernel for directed and residual reverberations. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Caviedes-Nozal et al. [2021] Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Caviedes-Nozal, D., Riis, N.A., Heuchel, F.M., Brunskog, J., Gerstoft, P., Fernandez-Grande, E.: Gaussian processes for sound field reconstruction. The Journal of the Acoustical Society of America 149(2), 1107–1119 (2021) McCormack et al. [2022] McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- McCormack, L., Politis, A., Gonzalez, R., Lokki, T., Pulkki, V.: Parametric ambisonic encoding of arbitrary microphone arrays. IEEE/ACM Transactions on Audio, Speech, and Language Processing 30, 2062–2075 (2022) https://doi.org/10.1109/TASLP.2022.3182857 Pezzoli et al. [2020] Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pezzoli, M., Borra, F., Antonacci, F., Tubaro, S., Sarti, A.: A parametric approach to virtual miking for sources of arbitrary directivity. IEEE/ACM Transactions on Audio, Speech, and Language Processing 28, 2333–2348 (2020) Thiergart et al. [2013] Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Thiergart, O., Del Galdo, G., Taseska, M., Habets, E.A.: Geometry-based spatial sound acquisition using distributed microphone arrays. IEEE transactions on audio, speech, and language processing 21(12), 2583–2594 (2013) Gannot et al. [2017] Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Gannot, S., Vincent, E., Markovich-Golan, S., Ozerov, A.: A consolidated perspective on multimicrophone speech enhancement and source separation. IEEE/ACM Trans. on Audio, Speech, and Language Process. 25(4), 692–730 (2017) Mignot et al. [2013] Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Mignot, R., Chardon, G., Daudet, L.: Low frequency interpolation of room impulse responses using compressed sensing. IEEE/ACM Transactions on Audio, Speech, and Language Processing 22(1), 205–216 (2013) Jin and Kleijn [2015] Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Jin, W., Kleijn, W.B.: Theory and design of multizone soundfield reproduction using sparse methods. IEEE/ACM Transactions on Audio, Speech, and Language Processing 23(12), 2343–2355 (2015) Olivieri et al. [2021a] Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Olivieri, M., Pezzoli, M., Antonacci, F., Sarti, A.: A physics-informed neural network approach for nearfield acoustic holography. Sensors 21(23), 7834 (2021) Olivieri et al. [2021b] Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Olivieri, M., Malvermi, R., Pezzoli, M., Zanoni, M., Gonzalez, S., Antonacci, F., Sarti, A.: Audio information retrieval and musical acoustics. IEEE Instrumentation & Measurement Magazine 24(7), 10–20 (2021) Olivieri et al. [2023] Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Olivieri, M., Comanducci, L., Pezzoli, M., Balsarri, D., Menescardi, L., Buccoli, M., Pecorino, S., Grosso, A., Antonacci, F., Sarti, A.: Real-time multichannel speech separation and enhancement using a beamspace-domain-based lightweight cnn. In: ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5 (2023). IEEE Karakonstantis and Fernandez Grande [2021] Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Karakonstantis, X., Fernandez Grande, E.: Sound field reconstruction in rooms with deep generative models. In: INTER-NOISE and NOISE-CON Congress and Conference Proceedings, vol. 263, pp. 1527–1538 (2021). Institute of Noise Control Engineering Fernandez-Grande et al. [2023] Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Fernandez-Grande, E., Karakonstantis, X., Caviedes-Nozal, D., Gerstoft, P.: Generative models for sound field reconstruction. The Journal of the Acoustical Society of America 153(2), 1179–1190 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Karakonstantis, X., Fernandez-Grande, E.: Generative adversarial networks with physical sound field priors. The Journal of the Acoustical Society of America 154(2), 1226–1238 (2023) Miotello et al. [2023] Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Miotello, F., Comanducci, L., Pezzoli, M., Bernardini, A., Antonacci, F., Sarti, A.: Reconstruction of sound field through diffusion models. arXiv preprint arXiv:2312.08821 (2023) Ulyanov et al. [2018] Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Ulyanov, D., Vedaldi, A., Lempitsky, V.: Deep image prior. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 9446–9454 (2018) Shigemi et al. [2022] Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Shigemi, K., Koyama, S., Nakamura, T., Saruwatari, H.: Physics-informed convolutional neural network with bicubic spline interpolation for sound field estimation. In: 2022 International Workshop on Acoustic Signal Enhancement (IWAENC), pp. 1–5 (2022). IEEE Williams [1999] Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Williams, E.G.: Fourier Acoustics: Sound Radiation and Nearfield Acoustical Holography. Elsevier, ??? (1999) Baydin et al. [2018] Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Baydin, A.G., Pearlmutter, B.A., Radul, A.A., Siskind, J.M.: Automatic differentiation in machine learning: a survey. Journal of Marchine Learning Research 18, 1–43 (2018) Raissi et al. [2019] Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Raissi, M., Perdikaris, P., Karniadakis, G.E.: Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707 (2019) Pezzoli et al. [2023] Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Pezzoli, M., Antonacci, F., Sarti, A.: Implicit neural representation with physics-informed neural networks for the reconstruction of the early part of room impulse responses. Forum Acusticum 2023 (2023) Karakonstantis and Fernandez-Grande [2023] Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Karakonstantis, X., Fernandez-Grande, E.: Room impulse response reconstuction using physics-constrained neural networks. Forum Acusticum 2023 (2023) Karakonstantis et al. [2024] Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Karakonstantis, X., Caviedes-Nozal, D., Richard, A., Fernandez-Grande, E.: Room impulse response reconstruction with physics-informed deep learning. arXiv preprint arXiv:2401.01206 (2024) Sitzmann et al. [2020] Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Sitzmann, V., Martel, J., Bergman, A., Lindell, D., Wetzstein, G.: Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473 (2020) Koyama et al. [2021] Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Koyama, S., Nishida, T., Kimura, K., Abe, T., Ueno, N., Brunnström, J.: Meshrir: A dataset of room impulse responses on meshed grid points for evaluating sound field analysis and synthesis methods. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 1–5 (2021). IEEE Stan et al. [2002] Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Stan, G.B., Embrechts, J.J., Archambeau, D.: Comparison of different impulse response measurement techniques. Journal of the Audio engineering society 50(4), 249–262 (2002) Farina [2007] Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Farina, A.: Advancements in impulse response measurements by sine sweeps. In: Audio Engineering Society Convention 122 (2007). Audio Engineering Society Damiano et al. [2021] Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Damiano, S., Borra, F., Bernardini, A., Antonacci, F., Sarti, A.: Soundfield reconstruction in reverberant rooms based on compressive sensing and image-source models of early reflections. In: 2021 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (WASPAA), pp. 366–370 (2021). IEEE Zea [2019] Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Zea, E.: Compressed sensing of impulse responses in rooms of unknown properties and contents. Journal of Sound and Vibration 459, 114871 (2019) Fernandez-Grande et al. [2021] Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Fernandez-Grande, E., Caviedes-Nozal, D., Hahmann, M., Karakonstantis, X., Verburg, S.A.: Reconstruction of room impulse responses over extended domains for navigable sound field reproduction. In: 2021 Immersive and 3D Audio: from Architecture to Automotive (I3DA), pp. 1–8 (2021). IEEE Hornik et al. [1989] Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Hornik, K., Stinchcombe, M., White, H.: Multilayer feedforward networks are universal approximators. Neural networks 2(5), 359–366 (1989) Kingma and Ba [2015] Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015) Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
- Kingma, D.P., Ba, J.: Adam: A method for stochastic optimization. In: ICLR (Poster) (2015)
Paper Prompts
Sign up for free to create and run prompts on this paper using GPT-5.
Top Community Prompts
Collections
Sign up for free to add this paper to one or more collections.
