Deep Neural Network-assisted improvement of quantum compressed sensing tomography
Abstract: Quantum compressed sensing is the fundamental tool for low-rank density matrix tomographic reconstruction in the informationally incomplete case. We examine situations where the acquired information is not enough to allow one to obtain a precise compressed sensing reconstruction. In this scenario, we propose a Deep Neural Network-based post-processing to improve the initial reconstruction provided by compressed sensing. The idea is to treat the estimated state as a noisy input for the network and perform a deep-supervised denoising task. After the network is applied, a projection onto the space of feasible density matrices is performed to obtain an improved final state estimation. We demonstrate through numerical experiments the improvement obtained by the denoising process and exploit the possibility of looping the inference scheme to obtain further advantages. Finally, we test the resilience of the approach to out-of-distribution data.
- M. A. Nielsen and I. L. Chuang, Quantum computation and quantum information (Cambridge university press, 2010).
- C. Granade, C. Ferrie, and S. T. Flammia, Practical adaptive quantum tomography*, New Journal of Physics 19, 113017 (2017).
- F. Huszár and N. M. T. Houlsby, Adaptive bayesian quantum tomography, Phys. Rev. A 85, 052120 (2012).
- K. Zheng, K. Li, and S. Cong, A reconstruction algorithm for compressive quantum tomography using various measurement sets, Scientific Reports 6 (2016).
- G. Carleo and M. Troyer, Solving the quantum many-body problem with artificial neural networks, Science 355, 602 (2017).
- A. W. R. Smith, J. Gray, and M. S. Kim, Efficient quantum state sample tomography with basis-dependent neural networks, PRX Quantum 2, 020348 (2021).
- T. Schmale, M. Reh, and M. Gärttner, Efficient quantum state tomography with convolutional neural networks, npj Quantum Information 8 (2022).
- Y. Quek, S. Fort, and H. K. Ng, Adaptive quantum state tomography with neural networks, npj Quantum Information 7 (2021).
- C. Pan and J. Zhang, Deep learning-based quantum state tomography with imperfect measurement, International Journal of Theoretical Physics 61 (2022).
- H. Zhao, G. Carleo, and F. Vicentini, Empirical sample complexity of neural network mixed state reconstruction (2023), arXiv:2307.01840 [quant-ph] .
- A. M. Nguyen, J. Yosinski, and J. Clune, Deep neural networks are easily fooled: High confidence predictions for unrecognizable images, 2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR) , 427 (2014).
- I. Goodfellow, Y. Bengio, and A. Courville, Deep Learning (MIT Press, 2016) http://www.deeplearningbook.org.
- J. Carrasquilla and G. Torlai, How to use neural networks to investigate quantum many-body physics, PRX Quantum 2, 040201 (2021).
- V. L. Girko, Distribution of eigenvalues and eigenvectors of orthogonal random matrices, Ukrainian Mathematical Journal 37, 457–463 (1986).
- M. Lee, Mathematical analysis and performance evaluation of the gelu activation function in deep learning, Journal of Mathematics 2023, 1–13 (2023).
- J. Guo, N. Jia, and J. Bai, Transformer based on channel-spatial attention for accurate classification of scenes in remote sensing image, Scientific Reports 12 (2022).
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