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Mind the Exit Pupil Gap: Revisiting the Intrinsics of a Standard Plenoptic Camera (2402.12891v2)

Published 20 Feb 2024 in cs.CV

Abstract: Among the common applications of plenoptic cameras are depth reconstruction and post-shot refocusing. These require a calibration relating the camera-side light field to that of the scene. Numerous methods with this goal have been developed based on thin lens models for the plenoptic camera's main lens and microlenses. Our work addresses the often-overlooked role of the main lens exit pupil in these models and specifically in the decoding process of standard plenoptic camera (SPC) images. We formally deduce the connection between the refocusing distance and the resampling parameter for the decoded light field and provide an analysis of the errors that arise when the exit pupil is not considered. In addition, previous work is revisited with respect to the exit pupil's role and all theoretical results are validated through a ray-tracing-based simulation. With the public release of the evaluated SPC designs alongside our simulation and experimental data we aim to contribute to a more accurate and nuanced understanding of plenoptic camera optics.

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References (38)
  1. Lippmann, G. Epreuves reversibles, photographies integrales. Academie des sciences, 446451 1908.
  2. Ives, H.E. A camera for making parallax panoramagrams. JOSA 1928, 17, 435–439.
  3. Single lens stereo with a plenoptic camera. IEEE transactions on pattern analysis and machine intelligence 1992, 14, 99–106.
  4. Light field photography with a hand-held plenoptic camera. Computer Science Technical Report CSTR 2005, 2, 1–11.
  5. Light field camera design for integral view photography. Adobe Technical Report 2006.
  6. Single lens 3D-camera with extended depth-of-field. In Proceedings of the Human Vision and Electronic Imaging XVII. International Society for Optics and Photonics, 2012, Vol. 8291, p. 829108.
  7. Decoding, calibration and rectification for lenselet-based plenoptic cameras. In Proceedings of the Computer Vision and Pattern Recognition (CVPR), 2013 IEEE Conference on. IEEE, 2013, pp. 1027–1034.
  8. Baseline and triangulation geometry in a standard plenoptic camera. International Journal of Computer Vision 2018, 126, 21–35.
  9. Focus model for metric depth estimation in standard plenoptic cameras. ISPRS Journal of Photogrammetry and Remote Sensing 2018, 144, 38–47.
  10. Refocusing distance of a standard plenoptic camera. Optics Express 2016, 24, 21521–21540.
  11. A generic multi-projection-center model and calibration method for light field cameras. IEEE transactions on pattern analysis and machine intelligence 2018, 41, 2539–2552.
  12. Standard plenoptic cameras mapping to camera arrays and calibration based on DLT. IEEE Transactions on Circuits and Systems for Video Technology 2019, 30, 4090–4099.
  13. Focal stack based light field coding for refocusing applications. In Proceedings of the 2019 IEEE International Symposium on Broadband Multimedia Systems and Broadcasting (BMSB). IEEE, 2019, pp. 1–4.
  14. The focused plenoptic camera. In Proceedings of the Computational Photography (ICCP), 2009 IEEE International Conference on. IEEE, 2009, pp. 1–8.
  15. Geometric calibration of micro-lens-based light field cameras using line features. IEEE transactions on pattern analysis and machine intelligence 2016, 39, 287–300.
  16. Microlens array grid estimation, light field decoding, and calibration. IEEE transactions on computational imaging 2020, 6, 591–603.
  17. A vignetting model for light field cameras with an application to light field microscopy. IEEE transactions on computational imaging 2019, 5, 585–595.
  18. A realistic camera model for computer graphics. In Proceedings of the Proceedings of the 22nd annual conference on computer graphics and interactive techniques, 1995, pp. 317–324.
  19. An Accurate and Practical Camera Lens Model for Rendering Realistic Lens Effects. In Proceedings of the Computer-Aided Design and Computer Graphics (CAD/Graphics), 2011 12th International Conference on. IEEE, 2011, pp. 63–70.
  20. NeuroLens: Data-Driven Camera Lens Simulation Using Neural Networks. In Proceedings of the Computer Graphics Forum. Wiley Online Library, 2017, Vol. 36, pp. 390–401.
  21. Lens-based depth estimation for multi-focus plenoptic cameras. In Proceedings of the German Conference on Pattern Recognition. Springer, 2014, pp. 410–420.
  22. Reconstruction of refocusing and all-in-focus images based on forward simulation model of plenoptic camera. Optics Communications 2015, 357, 1–6.
  23. A light transport framework for lenslet light field cameras. ACM Transactions on Graphics (TOG) 2015, 34, 16.
  24. A simulation framework for the design and evaluation of computational cameras. In Proceedings of the Automated Visual Inspection and Machine Vision III. International Society for Optics and Photonics, 2019, Vol. 11061, p. 1106102.
  25. Simulation of plenoptic cameras. In Proceedings of the 2018-3DTV-Conference: The True Vision-Capture, Transmission and Display of 3D Video (3DTV-CON). IEEE, 2018, pp. 1–4.
  26. Principles of optics: electromagnetic theory of propagation, interference and diffraction of light; Elsevier, 2013.
  27. Smith, W.J. Modern optical engineering: the design of optical systems; McGraw-Hill Education, 2008.
  28. Light field rendering. In Seminal Graphics Papers: Pushing the Boundaries, Volume 2; 2023; pp. 441–452.
  29. Ng, R. Fourier slice photography. In ACM Siggraph 2005 Papers; 2005; pp. 735–744.
  30. Carl Zeiss AG, Datasheet: Zeiss Planar T* 2/80 Lens Datasheet. https://www.zeiss.de/content/dam/consumer-products/downloads/historical-products/photography/contax-645/de/datasheet-zeiss-planar-280-de.pdf. Accessed: 01-12-2024.
  31. Carl Zeiss AG, Datasheet: Zeiss Zeiss Sonnar T* 2.8/140. https://www.zeiss.de/content/dam/consumer-products/downloads/historical-products/photography/contax-645/de/datasheet-zeiss-sonnar-28140-de.pdf. Accessed: 01-12-2024.
  32. Claff, W.J. https://www.photonstophotos.net. Accessed: 01-12-2024.
  33. Blender Foundation. https://www.blender.org/. Accessed: 01-12-2024.
  34. Ray tracing-guided design of plenoptic cameras. In Proceedings of the 2021 International Conference on 3D Vision (3DV). IEEE, 2021, pp. 1125–1133.
  35. Yu, W. Practical anti-vignetting methods for digital cameras. IEEE Transactions on Consumer Electronics 2004, 50, 975–983.
  36. Analysis of focus measure operators for shape-from-focus. Pattern Recognition 2013, 46, 1415–1432.
  37. Edge diffraction in Monte Carlo ray tracing. In Proceedings of the Optical design and analysis software. SPIE, 1999, Vol. 3780, pp. 151–157.
  38. Monte Carlo ray-trace diffraction based on the Huygens–Fresnel principle. Applied optics 2018, 57, D56–D62.

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