Resources for phase recovery

Here, we refer to the process of “calculating the phase of a light field from its amplitude/intensity measurements” as phase recovery (PR). It contains many techniques and algorithms, such as holography/interferometry, transport of intensity equation (TIE), phase retrieval (optimization-based approaches), wavefront sensing, and deep-learning-based approaches.

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Table of contents:

• Contributing
• People or groups (More people and groups in Computational Imaging)
  • Asia
  • Americas
  • Europe
  • Oceania
• Companies
• Workshops or courses (video or slides available)
• Research papers
  • Conventional phase recovery
    • Holography/Interferometry
    • Transport of intensity equation
    • Wavefront-sensing-based approaches
    • Optimization-based approaches
      • Alternating projection (AP)
      • Axial multi-intensity AP
      • Radial multi-intensity AP
      • Angular multi-intensity AP
      • Non-convex optimization
      • Convex optimization
  • Deep-learning(DL)-based phase recovery
    • DL-pre-processing for phase recovery
      • Pixel super-resolution
      • Noise reduction
      • Hologram generation
      • Autofocusing
    • DL-in-processing for phase recovery
      • Dataset-driven (DD) network-only strategy
      • Physics-driven (PD) network-only strategy
      • Physics-connect-network (PcN) strategy
      • Network-in-physics (NiP) strategy
      • Physics-in-network (PiN) strategy
    • DL-post-processing for phase recovery
      • Noise reduction
      • Resolution enhancement
      • Aberration correction
      • Phase unwrapping
    • DL for phase processing
      • Segmentation
      • Classification
      • Imaging modal transformation
• Review / Tutorial papers
  • Conventional phase recovery
  • Deep-learning-based phase recovery
• Books
• Dissertations and Thesis

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Contributing

You are welcome to join as a contributor, by adding or modifying relevant content via the "fork and pull request".

Please use the following guidelines:

• Edit the raw file with Markdown Syntax.
• Avoid typos.
• Don't add what's already there.
• Uniform the format of new additions with that of the existing.
• Note the order of new additions (chronological or alphabetical).

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People and groups

(In alphabetical order according to surnames)
Quick search by "Ctrl + F" with the following keywords:
phase imaging, holography, interferometry, phase retrieval, Fourier ptychography, inverse problem, transport of intensity equation, wavefront sensing, adaptive optics, phase unwrapping, fringe analysis, coherent diffractive imaging, optical diffraction tomography, computational imaging, biomedical imaging

Asia

• Arun Anand (Sardar Patel University)
  Keywords: holography and biomedical imaging etc.

• Anand Asundi (d'Optron Pte Ltd)
  Keywords: phase imaging, holography, and transport of intensity equation (TIE) etc.

• Liheng Bian (Beijing Institute of Technology)
  Keywords: phase retrieval etc.

• Liangcai Cao (Tsinghua University)
  Keywords: holography etc.

• Wen Chen (The Hong Kong Polytechnic University)
  Keywords: holography and single-pixel imaging etc.

• Chau-Jern Cheng (National Taiwan Normal University)
  Keywords: holography etc.

• Wonshik Choi (Korea university)
  Keywords: phase imaging and optical diffraction tomography etc.

• Zachary J. Smith and Kaiqin Chu (The University of Science and Technology of China)
  Keywords: phase imaging and super-resolution imaging etc.

• Qionghai Dai (Tsinghua university)
  Keywords: computational imaging and phase imaging etc.

• Shai Dekel (Tel-Aviv University)
  Keywords: phase retrieval etc.

• Jianglei Di (GuangDong University of Technology)
  Keywords: holography etc.

• Peng Gao (Xidian University)
  Keywords: phase imaging and super-resolution imaging etc.

• Ryoichi Horisaki (The University of Tokyo)
  Keywords: wavefront sensing, holography and computational imaging etc.

• Wolfgang Heidrich (King Abdullah University of Science and Technology)
  Keywords: wavefront sensing, phase imaging and computational imaging etc.

• Kedar Khare (Indian Institute of Technology Delhi)
  Keywords: holography, phase imaging, and computational imaging etc.

• Edmund Y. Lam (The University of Hong Kong)
  Keywords: phase retrieval, holography and computational imaging etc.

• Byoungho Lee (Seoul National University)
  Keywords: phase retrieval and holography etc.

• Cheng Liu (Jiangnan University)
  Keywords: phase imaging etc.

• Ne-Te Duane Loh (National University of Singapore)
  Keywords: phase retrieval and wavefront sensing etc.

• Daniel P.K. Lun (The Hong Kong Polytechnic University)
  Keywords: phase retrieval and computational imaging etc.

• Yuan Luo (National Taiwan University)
  Keywords: phase imaging etc.

• Dalip Singh Mehta (Indian Institute of Technology Delhi)
  Keywords: phase imaging and holograohy etc.

• Inkyu Moon (Daegu Gyeongbuk Institute of Science and Technology)
  Keywords: holograohy (in cell imaging and analysis) etc.

• Takanori Nomura (Wakayama University)
  Keywords: holography etc.

• An Pan (Chinese Academy of Sciences)
  Keywords: Fourier ptychography and phase imaging etc.

• Jung-Hoon Park (Ulsan National Institute of Science and Technology)
  Keywords: phase imaging and biomedical imaging etc.

• YongKeun Park (Korea Advanced Institute of Science and Technology)
  Keywords: phase imaging, optical diffraction tomography and biomedical imaging etc.

• Kemao Qian (Nanyang Technological University)
  Keywords: phase unwrapping and fringe analysis etc.

• Chenggen Quan (National University of Singapore)
  Keywords: phase retrieval and holography etc.

• Liyong Ren (Shaanxi Normal University)
  Keywords: phase unwrapping etc.

• Lu Rong (Beijing University of Technology)
  Keywords: phase retrieval, coherent diffractive imaging, and holography etc.

• Joseph Rosen (Ben-Gurion University of the Negev)
  Keywords: holography etc.

• Natan T. Shaked (Tel Aviv University)
  Keywords: interferometry, wavefront sensing, and biomedical imaging etc.

• Tomoyoshi Shimobaba (Chiba University)
  Keywords: holography and phase retrieval etc.

• Yoav Shechtman (Israel Institute of Technology)
  Keywords: phase retrieval etc.

• Guohai Situ (University of Chinese Academy of Sciences)
  Keywords: phase imaging, holography, and computational imaging etc.

• Yukio Takahashi (Tohoku University)
  Keywords: phase retrieval, holography, and coherent diffractive imaging etc.

• Xiaodi Tan (Fujian Normal University)
  Keywords: holography etc.

• Peter Wai Ming Tsang (City University of Hong Kong)
  Keywords: holography etc.

• Yang Wang (The Hong Kong University of Science and Technology)
  Keywords: phase retrieval etc.

• Dayong Wang (Beijing University of Technology)
  Keywords: holography etc.

• Masahiro Yamaguchi (Tokyo Institute of Technology)
  Keywords: holography (display) etc.

• Baoli Yao (University of Chinese Academy of Sciences)
  Keywords: holography and super-resolution imaging etc.

• Masayuki Yokota (Shimane University)
  Keywords: holography etc.

• Yingjie Yu (Shanghai University)
  Keywords: holography and computational imaging etc.

• Caojin Yuan (Nanjing Normal University)
  Keywords: holography etc.

• Fucai Zhang (Southern University of Science and Technology)
  Keywords: phase retrieval, wavefront sensing, and holography etc.

• Shaohui Zhang (Beijing Institute of Technology)
  Keywords: phase retrieval and Fourier ptychography etc.

• Yaping Zhang (Kunming University of Science and Technology)
  Keywords: holography etc.

• Jianlin Zhao (Northwestern Polytechnical University)
  Keywords: holography and computational imaging etc.

• Renjie Zhou (The Chinese University of Hong Kong)
  Keywords: phase imaging, optical diffraction tomography, and biomedical imaging etc.

• Chao Zuo (Nanjing University of Science and Technology)
  Keywords: transport of intensity equation (TIE), phase imaging, and computational imaging etc.

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Americas

• George Barbastathis (Massachusetts Institute of Technology)
  Keywords: inverse problem, phase imaging, holography, and computational imaging etc.

• Stephen Boppart (University of Illinois Urbana-Champaign)
  Keywords: wavefront sensing and biomedical imaging etc.

• David J Brady (University of Arizona)
  Keywords: (compressive) holography and computational imaging etc.

• Stanley H. Chan (Purdue University)
  Keywords: wavefront sensing etc.

• Ni Chen (University of Arizona)
  Keywords: differentiable holography, coherent diffraction imaging, differentiable imaging, and phase imaging etc.

• Mathew Cherukara (Argonne National Laboratory)
  Keywords: phase retrieval etc.

• Ana Doblas (University of Memphis)
  Keywords: holography and phase imaging etc.

• James R. Fienup (University of Rochester)
  Keywords: phase retrieval, coherent diffractive imaging, and wavefront sensing etc.

• Jason W. Fleischer (Mississippi State University)
  Keywords: phase retrieval etc.

• Joseph Goodman (Stanford University)
  Keywords: holography etc.

• Peter de Groot (Zygo Corporation)
  Ketwords: interferometry etc.

• Paul Hand (Northeastern University)
  Keywords: inverse problem and phase retrieval etc.

• Babak Hassibi (California Institute of Technology)
  Keywords: phase retrieval etc.

• Roarke Horstmeyer (Duke University)
  Keywords: Fourier ptychography and single-photon detection etc.

• Bahram Javidi (University of Connecticut)
  Keywords: holography etc.

• Rongguang Liang (The University of Arizona)
  Keywords: phase imaging, phase unwrapping and biomedical imaging etc.

• Christopher Metzler (The University of Maryland)
  Keywords: phase retrieval, inverse problem and computational imaging etc.

• Jianwei (John) Miao (University of California, Los Angeles)
  Keywords: coherent diffractive imaging and atomic electron tomography etc.

• David Nolte (Purdue University)
  Keywords: interferometry and holography etc.

• Aydogan Ozcan (University of California, Los Angeles)
  Keywords: phase imaging, holography, and lensless imaging etc.

• Ting-Chung Poon (Virginia Polytechnic Institute and State University)
  Keywords: holography etc.

• Gabriel Popescu (University of Illinois at Urbana-Champaign)
  Keywords: phase imaging, optical diffraction tomography and biomedical imaging etc.

• Mariano Rivera (Centro de Investigación en Matemáticas AC)
  Keywords: fringe analysis, phase retrieval, and phase unwrapping etc.

• Ian Robinson (Brookhaven National Laboratory)
  Keywords: phase retrieval and coherent diffractive imaging etc.

• Austin Roorda (University of California, Berkeley)
  Keywords: wavefront sensing and adaptive optics etc.

• Sujay Sanghavi (University of Texas, Austin)
  Keywords: phase retrieval etc.

• Philip Schniter (The Ohio State University)
  Keywords: inverse problem and phase retrieval etc.

• Mahdi Soltanolkotabi (University of Southern California)
  Keywords: phase retrieval and computational imaging etc.

• Adrian Stern (Ben-Gurion University of the Negev)
  Keywords: holography etc.

• Ju Sun (University of Minnesota)
  Keywords: inverse problem and phase retrieval etc.

• Enrique Tajahuerce (Universitat Jaume I)
  Keywords: holography and computational imaging etc.

• Michael Teitell (University of California, Los Angeles)
  Keywords: phase imaging and biomedical imaging etc.

• Lei Tian (Boston University)
  Keywords: Fourier ptychography, transport of intensity equation (TIE), and computational imaging etc.

• Carlos Alejandro Trujillo (EAFIT University)
  Keywords: holography and phase imaging etc.

• Ashok Veeraraghavan (Rice University)
  Keywords: wavefront sensing and lensless imaging etc.

• Kent Wallace (Jet Propulsion Laboratory)
  Keywords: wavefront sensing, interferometry, and holography etc.

• Laura Waller (University of California, Berkeley)
  Keywords: phase imaging, lensless imaging, and transport of intensity equation (TIE) etc.

• Congli Wang (University of California, Berkeley)
  Keywords: wavefront sensing, adaptive optics, and digital holography etc.

• Adam P. Wax (Duke University)
  Keywords: interferometry and biomedical imaging etc.

• Gordon Wetzstein (Stanford University)
  Keywords: holography (display) and computational imaging etc.

• Florian Willomitzer (University of Arizona)
  Keywords: synthetic wavelength holography and interferometry etc.

• Changhuei Yang (California Institute of Technology)
  Keywords: Fourier ptychography, wavefront shaping, and non-line-of-sight imaging etc.

• Zahid Yaqoob (Massachusetts Institute of Technology)
  Keywords: phase imaging etc.

• Thomas A. Zangle (University of Utah)
  Keywords: phase imaging and biomedical imaging etc.

• Guoan Zheng (University of Connecticut)
  Keywords: Fourier ptychography etc.

• Yunhui Zhu (Virginia Polytechnic Institute and State University)
  Ketwords: transport of intensity equation (TIE) and phase imaging etc.

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Europe

• Martin Booth (University of Oxford)
  Keywords: wavefront sensing and adaptive optics etc.

• Artur Carnicer (Universitat de Barcelona)
  Keywords: holography etc.

• Radim Chmelik (Brno University of Technology)
  Keywords: phase imaging and holography etc.

• Juergen Czarske (Dresden University of Technology)
  Keywords: holography and phase imaging etc.

• Loïc Denis (Université Jean Monnet)
  Keywords: holography, phase retrieval, and wavefront sensing etc.

• Karen Eguiazarian (Tampere University)
  Keywords: phase retrieval and computational imaging etc.

• Tomas Ekeberg (Uppsala University)
  Keywords: phase retrieval and coherent diffractive imaging etc.

• Pietro Ferraro (CNR-ISASI)
  Keywords: holography etc.

• Hans-Werner Fink (University of Zurich)
  Keywords: electron holography etc.

• Thierry Fusco (ONERA)
  Keywords: wavefront sensing and adaptive optics etc.

• Guillermo Gallego (Technische Universität Berlin)
  Keywords: 3D surface reconstruction etc.

• Sylvain Gigan (Sorbonne Université)
  Keywords: phase retrieval, imaging through scattering media, and computational imaging etc.

• Manuel Guizar-Sicairos (EPFL)
  Keywords: phase retrieval, coherent diffractive imaging, and holography etc.

• Stefan Harmeling (Technische Universität Dortmund)
  Keywords: phase retrieval etc.

• Maxime Jacquot (Université Bourgogne Franche-Comté)
  Keywords: holography etc.

• Vladimir Katkovnik (Tampere University of Technology)
  Keywords: phase retrieval and inverse problem etc.

• Aykut Koc (Bilkent University)
  Keywords: phase retrieval, inverse problem, and computational imaging etc.

• Christoph T. Koch (Humboldt University of Berlin)
  Keywords: phase retrieval and inverse problem etc.

• Malgorzata Kujawinska (Warsaw University of Technology)
  Keywords: holography, phase imaging, and biomedical imaging etc.

• Tatiana Latychevskaia (University of Zurich)
  Keywords: phase retrieval and holography etc.

• Filipe Maia (Uppsala University)
  Keywords: phase retrieval and coherent diffractive imaging etc.

• Pierre Marquet (Université Laval)
  Keywords: holography (holographic microscopy) etc.

• Pasquale Memmolo (CNR-ISASI)
  Keywords: holography etc.

• Thomas J. Naughton (National University of Ireland, Maynooth)
  Keywords: holography etc.

• Figen S. Oktem (Middle East Technical University)
  Keywords: phase retrieval, inverse problem, and computational imaging etc.

• Wolfgang Osten (University of Stuttgart)
  Keywords: interferometry and holography etc.

• Nikolay V. Petrov (ITMO University)
  Keywords: phase retrieval and holography etc.

• Demetri Psaltis (EPFL)
  Keywords: holography and optical diffraction tomography etc.

• Pascal Picart (Le Mans University)
  Keywords: holography and phase imaging etc.

• Benjamin Rappaz (EPFL)
  Keywords: holography (holographic microscopy) etc.

• John Rodenburg (The University of Sheffield)
  Keywords: phase retrieval, coherent diffractive imaging, and ptychography etc.

• Genaro Saavedra (Universitat de Valéncia)
  Keywords: holography, 3D imaging and 3D display etc.

• Juergen Schnekenburger (Muenster University)
  Keywords: holography etc.

• Latychevskaia Tatiana (University of Zurich)
  Keywords: holography, phase retrieval, and coherent diffractive imaging etc.

• Michael Unser (EPFL)
  Keywords: phase retrieval, phase unwrapping, transport of intensity equation (TIE), and biomedical imaging etc.

• Giovanni Volpe (Giovanni Volpe)
  Keywords: holography in biomedical and particle analysis etc.

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Oceania

• Andrew Lambert(University of New South Wales)
  Keywords: wavefront sensing and adaptive optics etc.

• Rainer Leitgeb (Medical University of Vienna)
  Keywords: holography and biomedical imaging etc.

• David Paganin (Monash University)
  Keywords: phase retrieval, coherent diffractive imaging, and phase imaging etc.

• Konstantin Pavlov (University of Canterbury)
  Keywords: phase retrieval and coherent diffractive imaging etc.

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Companies

(In alphabetical order)

• d'Optron
  Keywords: digital holographic microscopy etc.

• Holmarc Opto-Mechatronics
  Keywords: digital holographic microscopy, digital in-line holographic microscopy etc.

• Imaging Optic
  Keywords: wavefront sensing etc

• Lyncee Tec
  Keywords: digital holographic microscopy etc.

• Nanolive
  Keywords: optical diffraction tomography etc.

• Phase Holographic Imaging PHI AB
  Keywords: digital holographic microscopy etc.

• Phase Focus
  Keywords: phase retrieval etc.

• Phasics
  Keywords: wavefront sensing and quadriwave lateral shearing interferometry (QWLSI) etc.

• Phi Optics
  Keywords: holographic microscopy and spatial light interference microscopy (SLIM) etc.

• Telight
  Keywords: holographic microscopy etc.

• Tomocube
  Keywords: optical diffraction tomography etc.

• Trioptics
  Keywords: wavefront sensing and interferometry etc.

• Zygo
  Keywords: interferometer and coherence scanning interferometric (CSI) profiler etc.

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Workshops or courses (video or slides available)

(In chronological order)

• "Phase Retrieval" in BioXFEL (October 18 - 19, 2021)
• "Computational Microscopy" in IPAM (September 12 - December 16, 2022)
  • "Computational Microscopy Tutorials"(September 13-16, 2022)
  • "Diffractive Imaging with Phase Retrieval"(October 10-14, 2022)

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Research papers

(In chronological order)

Conventional phase recovery

(Here, we only mention the classic pioneering papers)

Holography/Interferometry

• D. Gabor
  A New Microscopic Principle
  Nature 161(4098), 777–778 (1948).
• E. N. Leith and J. Upatnieks
  Reconstructed Wavefronts and Communication Theory*
  J. Opt. Soc. Am. 52(10), 1123 (1962).
• I. Yamaguchi and T. Zhang
  Phase-shifting digital holography
  Opt. Lett. 22(16), 1268 (1997).
• G. Popescu, T. Ikeda, R. R. Dasari, and M. S. Feld
  Diffraction phase microscopy for quantifying cell structure and dynamics
  Opt. Lett. 31(6), 775 (2006).
• Z. Wang, L. Millet, M. Mir, H. Ding, S. Unarunotai, J. Rogers, M. U. Gillette, and G. Popescu
  Spatial light interference microscopy (SLIM)
  Opt. Express 19(2), 1016 (2011).

Transport of intensity equation

• J. P. Guigay
  Fourier transform analysis of Fresnel diffraction patterns and in-line holograms
  Optik 49, 121–125 (1977).
• D. Paganin and K. A. Nugent
  Noninterferometric Phase Imaging with Partially Coherent Light
  Phys. Rev. Lett. 80(12), 2586–2589 (1998).
• M. R. Teague
  Deterministic phase retrieval: a Green’s function solution
  J. Opt. Soc. Am. 73(11), 1434 (1983).

Wavefront-sensing-based approaches

(Mainly refers to the approaches of obtaining the phase gradient first and then integrating to calculate the phase)

• J. Hartmann
  Bemerkungen uber den Bau und die Justirung von Spektrographen
  Zeitschrift fuer Instrumentenkunde 20, 47–58 (1900).
• R. V. Shack and B. C. Platt
  Production and use of a lenticular Hartmann screen
  J. Opt. Soc. Am. 61, 656 (1971).
• J. S. Hartman, R. L. Gordon, and D. L. Lessor
  Development Of Nomarski Microscopy For Quantitative Determination Of Surface Topography(A)
  in G. W. Hopkins, ed. (1979), pp. 223–230. (Conference)
• P. Bon, G. Maucort, B. Wattellier, and S. Monneret
  Quadriwave lateral shearing interferometry for quantitative phase microscopy of living cells
  Opt. Express 17(15), 13080 (2009).

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Optimization-based approaches

Alternating projection

• R. W. Gerchberg
  A practical algorithm for determination of phase from image and diffraction plane pictures
  Optik 35, 237–246 (1972).
• J. R. Fienup
  Reconstruction of an object from the modulus of its Fourier transform
  Opt. Lett. 3(1), 27 (1978).
• J. R. Fienup
  Phase retrieval algorithms: a comparison
  Appl. Opt. 21(15), 2758 (1982).

Axial multi-intensity alternating projection (Multi-height phase retrieval)

• L. J. Allen and M. P. Oxley
  Phase retrieval from series of images obtained by defocus variation
  Optics Communications 199(1–4), 65–75 (2001).
• G. Pedrini, W. Osten, and Y. Zhang
  Wave-front reconstruction from a sequence of interferograms recorded at different planes
  Opt. Lett. 30(8), 833 (2005).
• A. Greenbaum and A. Ozcan
  Maskless imaging of dense samples using pixel super-resolution based multi-height lensfree on-chip microscopy
  Opt. Express 20(3), 3129 (2012).

Radial multi-intensity alternating projection (Real-space ptychography)

• H. M. L. Faulkner and J. M. Rodenburg
  Movable Aperture Lensless Transmission Microscopy: A Novel Phase Retrieval Algorithm
  Phys. Rev. Lett. 93(2), 023903 (2004).
• J. M. Rodenburg and H. M. L. Faulkner
  A phase retrieval algorithm for shifting illumination
  Appl. Phys. Lett. 85(20), 4795–4797 (2004).

Angular multi-intensity alternating projection (Fourier ptychography)

• G. Zheng, R. Horstmeyer, and C. Yang
  Wide-field, high-resolution Fourier ptychographic microscopy
  Nature Photon 7(9), 739–745 (2013).
• X. Ou, R. Horstmeyer, C. Yang, and G. Zheng
  Quantitative phase imaging via Fourier ptychographic microscopy
  Opt. Lett. 38(22), 4845 (2013).

Non-convex optimization

• E. J. Candes, X. Li, and M. Soltanolkotabi
  Phase Retrieval via Wirtinger Flow: Theory and Algorithms
  IEEE Trans. Inform. Theory 61(4), 1985–2007 (2015).
• G. Wang, G. B. Giannakis, and Y. C. Eldar
  Solving Systems of Random Quadratic Equations via Truncated Amplitude Flow
  IEEE Trans. Inform. Theory 64(2), 773–794 (2018).

Convex optimization

• E. J. Candès, T. Strohmer, and V. Voroninski
  PhaseLift: Exact and Stable Signal Recovery from Magnitude Measurements via Convex Programming
  Comm. Pure Appl. Math. 66(8), 1241–1274 (2013).

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Deep-learning(DL)-based phase recovery

DL-pre-processing for phase recovery

Pixel super-resolution

• Z. Luo, A. Yurt, R. Stahl, A. Lambrechts, V. Reumers, D. Braeken, and L. Lagae
  Pixel super-resolution for lens-free holographic microscopy using deep learning neural networks
  Opt. Express 27(10), 13581 (2019).
• H. Byeon, T. Go, and S. J. Lee
  Deep learning-based digital in-line holographic microscopy for high resolution with extended field of view
  Optics & Laser Technology 113, 77–86 (2019).
• Z. Ren, H. K.-H. So, and E. Y. Lam
  Fringe Pattern Improvement and Super-Resolution Using Deep Learning in Digital Holography
  IEEE Trans. Ind. Inf. 15(11), 6179–6186 (2019).
• L. Xin, X. Liu, Z. Yang, X. Zhang, Z. Gao, and Z. Liu
  Three-dimensional reconstruction of super-resolved white-light interferograms based on deep learning
  Optics and Lasers in Engineering 145, 106663 (2021).

Noise reduction

• K. Yan, Y. Yu, C. Huang, L. Sui, K. Qian, and A. Asundi
  Fringe pattern denoising based on deep learning
  Optics Communications 437, 148–152 (2019).
• F. Hao, C. Tang, M. Xu, and Z. Lei
  Batch denoising of ESPI fringe patterns based on convolutional neural network
  Appl. Opt. 58(13), 3338 (2019).
• W.-J. Zhou, S. Zou, D.-K. He, J.-L. Hu, H. Zhang, Y.-J. Yu, and T.-C. Poon
  Speckle noise reduction in digital holograms based on Spectral Convolutional Neural Networks (SCNN)
  in Holography, Diffractive Optics, and Applications IX, C. Zhou, Y. Sheng, and L. Cao, eds. (SPIE, 2019), p. 6.
• B. Lin, S. Fu, C. Zhang, F. Wang, and Y. Li
  Optical fringe patterns filtering based on multi-stage convolution neural network
  Optics and Lasers in Engineering 126, 105853 (2020).
• W.-J. Zhou, S. Liu, H. Zhang, Y. Yu, and T.-C. Poon
  A Deep Learning Approach for Digital Hologram Speckle Noise Reduction
  in Imaging and Applied Optics Congress (Optica Publishing Group, 2020), p. HTu5B.5.
• A. Reyes-Figueroa, V. H. Flores, and M. Rivera
  Deep neural network for fringe pattern filtering and normalization
  Appl. Opt. 60(7), 2022 (2021).
• J. Gurrola-Ramos, O. Dalmau, and T. Alarcón
  U-Net based neural network for fringe pattern denoising
  Optics and Lasers in Engineering 149, 106829 (2022).

Hologram generation

(for phase-shifting)

• Q. Zhang, S. Lu, J. Li, W. Li, D. Li, X. Lu, L. Zhong, and J. Tian
  Deep Phase Shifter for Quantitative Phase Imaging
  Preprint at arXiv (2020).
• Q. Zhang, S. Lu, J. Li, D. Li, X. Lu, L. Zhong, and J. Tian
  Phase-shifting interferometry from single frame in-line interferogram using deep learning phase-shifting technology
  Optics Communications 498, 127226 (2021).
• K. Yan, A. Khan, A. Asundi, Y. Zhang, and Y. Yu
  Virtual temporal phase-shifting phase extraction using generative adversarial networks
  Appl. Opt. 61(10), 2525 (2022).
• Y. Zhao, K. Hu, and F. Liu
  One-shot phase retrieval method for interferometry using a multi-stage phase-shifting network
  IEEE Photon. Technol. Lett. 35, 577–580 (2022).
• T. Huang, Q. Zhang, J. Li, X. Lu, J. Di, L. Zhong, and Y. Qin
  Single-shot Fresnel incoherent correlation holography via deep learning based phase-shifting technology
  Opt. Express 31(8), 12349 (2023).
• B. Wu, Q. Zhang, T. Liu, Q. Ma, and J. Li
  RSAGAN: Rapid self-attention generative adversarial nets for single-shot phase-shifting interferometry
  Optics and Lasers in Engineering 168, 107672 (2023).

(to different defocus distances)

• J. Gurrola-Ramos,
  Diffraction-Net: a robust single-shot holography for multi-distance lensless imaging
  Opt. Express 30(23), 41724 (2022).

(for multi-wavelength holography)

• J. Li, Q. Zhang, L. Zhong, J. Tian, G. Pedrini, and X. Lu
  Quantitative phase imaging in dual-wavelength interferometry using a single wavelength illumination and deep learning
  Opt. Express 28(19), 28140 (2020).
• J. Li, Q. Zhang, L. Zhong, and X. Lu
  Hybrid-net: a two-to-one deep learning framework for three-wavelength phase-shifting interferometry
  Opt. Express 29(21), 34656 (2021).
• X. Xu, M. Xie, Y. Ji, and Y. Wang
  Dual-wavelength interferogram decoupling method for three-frame generalized dual-wavelength phase-shifting interferometry based on deep learning
  J. Opt. Soc. Am. A 38(3), 321 (2021).

Autofocusing

(by classification)

• T. Pitkäaho, A. Manninen, and T. J. Naughton
  Performance of Autofocus Capability of Deep Convolutional Neural Networks in Digital Holographic Microscopy
  in Digital Holography and Three-Dimensional Imaging (OSA, 2017), p. W2A.5.
• T. Pitkäaho, A. Manninen, and T. J. Naughton
  Focus classification in digital holographic microscopy using deep convolutional neural networks
  in E. Beaurepaire, F. S. Pavone, and P. T. C. So, eds. (2017), p. 104140K.
• Z. Ren, Z. Xu, and E. Y. M. Lam
  Autofocusing in digital holography using deep learning
  in Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XXV (SPIE, 2018), p. 56.
• K. Son, W. Jeong, W. Jeon, and H. Yang
  Autofocusing algorithm for a digital holographic imaging system using convolutional neural networks
  Jpn. J. Appl. Phys. 57(9S1), 09SB02 (2018).
• R. Couturier, M. Salomon, E. A. Zeid, and C. A. Jaoude
  Using Deep Learning for Object Distance Prediction in Digital Holography
  in 2021 International Conference on Computer, Control and Robotics (ICCCR) (IEEE, 2021), pp. 231–235.

(by regression)

• Z. Ren, Z. Xu, and E. Y. Lam
  Learning-based nonparametric autofocusing for digital holography
  Optica 5(4), 337 (2018).
• J.-S. Lee
  Autofocusing using deep learning in off-axis digital holography
  in Imaging and Applied Optics 2018 (3D, AO, AIO, COSI, DH, IS, LACSEA, LS&C, MATH, PcAOP) (OSA, 2018), p. DTh1C.4.
• T. Shimobaba, T. Kakue, and T. Ito
  Convolutional Neural Network-Based Regression for Depth Prediction in Digital Holography
  in 2018 IEEE 27th International Symposium on Industrial Electronics (ISIE) (IEEE, 2018), pp. 1323–1326.
• T. Pitkäaho, A. Manninen, and T. J. Naughton
  Focus prediction in digital holographic microscopy using deep convolutional neural networks
  Appl. Opt. 58(5), A202 (2019).
• K. Jaferzadeh, S.-H. Hwang, I. Moon, and B. Javidi
  No-search focus prediction at the single cell level in digital holographic imaging with deep convolutional neural network
  Biomed. Opt. Express 10(8), 4276 (2019).
• I. Moon and K. Jaferzadeh
  Automated digital holographic image reconstruction with deep convolutional neural networks
  in Three-Dimensional Imaging, Visualization, and Display 2020, (SPIE, 2020), p. 10.
• S. Cuenat and R. Couturier
  Convolutional Neural Network (CNN) vs Vision Transformer (ViT) for Digital Holography
  in 2022 2nd International Conference on Computer, Control and Robotics (ICCCR) (IEEE, 2022), pp. 235–240.
• S. Cuenat, L. Andréoli, A. N. André, P. Sandoz, G. J. Laurent, R. Couturier, and M. Jacquot
  Fast autofocusing using tiny transformer networks for digital holographic microscopy
  Opt. Express 30(14), 24730 (2022).

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DL-in-processing for phase recovery

Dataset-driven (DD) network-only strategy

• A. Sinha, J. Lee, S. Li, and G. Barbastathis
  Lensless computational imaging through deep learning
  Optica 4(9), 1117 (2017).
• H. Wang, M. Lyu, and G. Situ
  eHoloNet: a learning-based end-to-end approach for in-line digital holographic reconstruction
  Opt. Express 26(18), 22603 (2018).
• T. Nguyen, Y. Xue, Y. Li, L. Tian, and G. Nehmetallah
  Deep learning approach for Fourier ptychography microscopy
  Opt. Express 26(20), 26470 (2018).
• S. Li and G. Barbastathis
  Spectral pre-modulation of training examples enhances the spatial resolution of the phase extraction neural network (PhENN)
  Opt. Express 26(22), 29340 (2018).
• M. J. Cherukara, Y. S. G. Nashed, and R. J. Harder
  Real-time coherent diffraction inversion using deep generative networks
  Sci Rep 8(1), 16520 (2018).
• A. Goy, K. Arthur, S. Li, and G. Barbastathis
  Low Photon Count Phase Retrieval Using Deep Learning
  Phys. Rev. Lett. 121(24), 243902 (2018).
• Y. F. Cheng, M. Strachan, Z. Weiss, M. Deb, D. Carone, and V. Ganapati
  Illumination pattern design with deep learning for single-shot Fourier ptychographic microscopy
  Opt. Express 27(2), 644 (2019).
• Z. Ren, Z. Xu, and E. Y. Lam
  End-to-end deep learning framework for digital holographic reconstruction
  Adv. Photon. 1(01), 1 (2019).
• X. Li, H. Qi, S. Jiang, P. Song, G. Zheng, and Y. Zhang
  Quantitative phase imaging via a cGAN network with dual intensity images captured under centrosymmetric illumination
  Opt. Lett. 44(11), 2879 (2019).
• K. Wang, J. Dou, Q. Kemao, J. Di, and J. Zhao
  Y-Net: a one-to-two deep learning framework for digital holographic reconstruction
  Opt. Lett. 44(19), 4765 (2019).
• Y. Nishizaki, R. Horisaki, K. Kitaguchi, M. Saito, and J. Tanida
  Analysis of non-iterative phase retrieval based on machine learning
  Opt Rev 27(1), 136–141 (2020).
• T. Zeng, H. K.-H. So, and E. Y. Lam
  RedCap: residual encoder-decoder capsule network for holographic image reconstruction
  Opt. Express 28(4), 4876 (2020).
• D. Yin, Z. Gu, Y. Zhang, F. Gu, S. Nie, J. Ma, and C. Yuan
  Digital Holographic Reconstruction Based on Deep Learning Framework With Unpaired Data
  IEEE Photonics J. 12(2), 1–12 (2020).
• L. Hu, S. Hu, W. Gong, and K. Si
  Deep learning assisted Shack–Hartmann wavefront sensor for direct wavefront detection
  Opt. Lett. 45(13), 3741 (2020).
• K. Wang, Q. Kemao, J. Di, and J. Zha
  Y4-Net: a deep learning solution to one-shot dual-wavelength digital holographic reconstruction
  Opt. Lett. 45(15), 4220 (2020).
• M. Deng, S. Li, Z. Zhang, I. Kang, N. X. Fang, and G. Barbastathis
  On the interplay between physical and content priors in deep learning for computational imaging
  Opt. Express 28(16), 24152 (2020).
• K. Wang, J. Di, Y. Li, Z. Ren, Q. Kemao, and J. Zhao
  Transport of intensity equation from a single intensity image via deep learning
  Opt. Lasers Eng. 134, 106233 (2020).
• L. Wu, P. Juhas, S. Yoo, and I. Robinson
  Complex imaging of phase domains by deep neural networks
  IUCrJ 8(1), 12–21 (2021).
• L. Huang, T. Liu, X. Yang, Y. Luo, Y. Rivenson, and A. Ozcan
  Holographic Image Reconstruction with Phase Recovery and Autofocusing Using Recurrent Neural Networks
  ACS Photonics 8(6), 1763–1774 (2021).
• T. Uelwer, T. Hoffmann, and S. Harmeling
  Non-iterative Phase Retrieval with Cascaded Neural Networks
  in Artificial Neural Networks and Machine Learning – ICANN 2021 (Springer International Publishing, 2021), 12892, pp. 295–306.
• R. Castaneda, C. Trujillo, and A. Doblas
  Video-Rate Quantitative Phase Imaging Using a Digital Holographic Microscope and a Generative Adversarial Network
  Sensors 21(23), 8021 (2021).
• D. Pirone, D. Sirico, L. Miccio, V. Bianco, M. Mugnano, P. Ferraro, and P. Memmolo
  Speeding up reconstruction of 3D tomograms in holographic flow cytometry via deep learning
  Lab Chip 22(4), 793–804 (2022).
• W. Luo, Y. Zhang, X. Shu, M. Niu, and R. Zhou
  Learning end-to-end phase retrieval using only one interferogram with mixed-context network
  in Quantitative Phase Imaging VIII, G. Popescu, Y. Park, and Y. Liu, eds. (SPIE, 2022), p. 26.
• K. Jaferzadeh and T. Fevens
  HoloPhaseNet: fully automated deep-learning-based hologram reconstruction using a conditional generative adversarial model
  Biomed. Opt. Express 13(7), 4032 (2022).
• H. Ding, F. Li, X. Chen, J. Ma, S. Nie, R. Ye, and C. Yuan
  ContransGAN: Convolutional Neural Network Coupling Global Swin-Transformer Network for High-Resolution Quantitative Phase Imaging with Unpaired Data
  Cells 11(15), 2394 (2022).
• H. Chen, L. Huang, T. Liu, and A. Ozcan
  Fourier Imager Network (FIN): A deep neural network for hologram reconstruction with superior external generalization
  Light Sci Appl 11(1), 254 (2022).
• Q. Ye, L.-W. Wang, and D. P. K. Lun
  SiSPRNet: end-to-end learning for single-shot phase retrieval
  Opt. Express 30(18), 31937 (2022).
• X. Shu, M. Niu, Y. Zhang, and R. Zhou
  NAS-PRNet: Neural Architecture Search generated Phase Retrieval Net for Off-axis Quantitative Phase Imaging
  Preprint at arXiv (2022).
• C. Lee, G. Song, H. Kim, J. C. Ye, and M. Jang
  Deep learning based on parameterized physical forward model for adaptive holographic imaging with unpaired data
  Nat Mach Intell 5, 35–45 (2023).
• H. Chen, L. Huang, T. Liu, and A. Ozcan
  eFIN: Enhanced Fourier Imager Network for Generalizable Autofocusing and Pixel Super-Resolution in Holographic Imaging
  PhysIEEE J. Select. Topics Quantum Electron. 29(4: Biophotonics), 1–10 (2023).

(Distortion intensity of target objects → Network → Wavefront phase or its Zernike coefficient)
(Applications in Adaptive Optics)

• Y. Nishizaki, M. Valdivia, R. Horisaki, K. Kitaguchi, M. Saito, J. Tanida, and E. Vera
  Deep learning wavefront sensing
  Opt. Express 27(1), 240 (2019).
• H. Ma, H. Liu, Y. Qiao, X. Li, and W. Zhang
  Numerical study of adaptive optics compensation based on Convolutional Neural Networks
  Optics Communications 433, 283–289 (2019).
• Q. Tian, C. Lu, B. Liu, L. Zhu, X. Pan, Q. Zhang, L. Yang, F. Tian, and X. Xin
  DNN-based aberration correction in a wavefront sensorless adaptive optics system
  Opt. Express 27(8), 10765 (2019).
• J. Liu, P. Wang, X. Zhang, Y. He, X. Zhou, H. Ye, Y. Li, S. Xu, S. Chen, and D. Fan
  Deep learning based atmospheric turbulence compensation for orbital angular momentum beam distortion and communication
  Opt. Express 27(12), 16671 (2019).
• Y. Zhang, C. Wu, Y. Song, K. Si, Y. Zheng, L. Hu, J. Chen, L. Tang, and W. Gong
  Machine learning based adaptive optics for doughnut-shaped beam
  Opt. Express 27(12), 16871 (2019).
• H. Guo, Y. Xu, Q. Li, S. Du, D. He, Q. Wang, and Y. Huang
  Improved Machine Learning Approach for Wavefront Sensing
  Sensors 19(16), 3533 (2019).
• Y. Xu, D. He, Q. Wang, H. Guo, Q. Li, Z. Xie, and Y. Huang
  An Improved Method of Measuring Wavefront Aberration Based on Image with Machine Learning in Free Space Optical Communication
  Sensors 19(17), 3665 (2019).
• Q. Xin, G. Ju, C. Zhang, and S. Xu
  Object-independent image-based wavefront sensing approach using phase diversity images and deep learning
  Opt. Express 27(18), 26102 (2019).
• T. Andersen, M. Owner-Petersen, and A. Enmark
  Neural networks for image-based wavefront sensing for astronomy
  Opt. Lett. 44(18), 4618 (2019).
• B. P. Cumming, M. Gu, and M. Gu
  Direct determination of aberration functions in microscopy by an artificial neural network
  Opt. Express, OE 28(10), 14511–14521 (2020).
• I. Vishniakou and J. D. Seelig
  Wavefront correction for adaptive optics with reflected light and deep neural networks
  Opt. Express 28(10), 15459 (2020).
• Y. Wu, Y. Guo, H. Bao, and C. Rao
  Sub-Millisecond Phase Retrieval for Phase-Diversity Wavefront Sensor
  Sensors 20(17), 4877 (2020).
• X. Wang, T. Wu, C. Dong, H. Zhu, Z. Zhu, and S. Zhao
  Integrating deep learning to achieve phase compensation for free-space orbital-angular-momentum-encoded quantum key distribution under atmospheric turbulence
  Photon. Res. 9(2), B9 (2021).
• E. Vera, F. Guzmán, and C. Weinberger
  Boosting the deep learning wavefront sensor for real-time applications
  Appl. Opt. 60(10), B119 (2021).
• Y. He, Z. Liu, Y. Ning, J. Li, X. Xu, and Z. Jiang
  Deep learning wavefront sensing method for Shack-Hartmann sensors with sparse sub-apertures
  Opt. Express 29(11), 17669 (2021).
• S. Hu, L. Hu, W. Gong, Z. Li, and K. Si
  Deep learning based wavefront sensor for complex wavefront detection in adaptive optical microscopes
  Front Inform Technol Electron Eng 22(10), 1277–1288 (2021).
• K. Wang, M. Zhang, J. Tang, L. Wang, L. Hu, X. Wu, W. Li, J. Di, G. Liu, and J. Zhao
  Deep learning wavefront sensing and aberration correction in atmospheric turbulence
  PhotoniX 2(1), 8 (2021).

Physics-driven (PD) network-only strategy

(with untrained/initialized networks)

• L. Boominathan, M. Maniparambil, H. Gupta, R. Baburajan, and K. Mitra
  Phase retrieval for Fourier Ptychography under varying amount of measurements
  Preprint at arXiv (2018).
• F. Wang, Y. Bian, H. Wang, M. Lyu, G. Pedrini, W. Osten, G. Barbastathis, and G. Situ
  Phase imaging with an untrained neural network
  Light Sci Appl 9(1), 77 (2020).
• D. Yang, J. Zhang, Y. Tao, W. Lv, S. Lu, H. Chen, W. Xu, and Y. Shi
  Dynamic coherent diffractive imaging with a physics-driven untrained learning method
  Opt. Express 29(20), 31426 (2021).
• C. Bai, T. Peng, J. Min, R. Li, Y. Zhou, and B. Yao
  Dual-wavelength in-line digital holography with untrained deep neural networks
  Photon. Res. 9(12), 2501 (2021).
• X. Zhang, F. Wang, and G. Situ
  BlindNet: an untrained learning approach toward computational imaging with model uncertaint
  J. Phys. D: Appl. Phys. 55(3), 034001 (2022).
• D. Yang, J. Zhang, Y. Tao, W. Lv, Y. Zhu, T. Ruan, H. Chen, X. Jin, Z. Wang, J. Qiu, and Y. Shi
  Coherent modulation imaging using a physics-driven neural network
  Opt. Express 30(20), 35647 (2022).
• A. S. Galande, V. Thapa, H. P. R. Gurram, and R. John
  Untrained deep network powered with explicit denoiser for phase recovery in inline holography
  Appl. Phys. Lett. 122(13), 133701 (2023).

(with trained networks)

• Y. Yao, H. Chan, S. Sankaranarayanan, P. Balaprakash, R. J. Harder, and M. J. Cherukara
  AutoPhaseNN: unsupervised physics-aware deep learning of 3D nanoscale Bragg coherent diffraction imagin
  npj Comput Mater 8(1), 124 (2022).
• R. Li, G. Pedrini, Z. Huang, S. Reichelt, and L. Cao
  Physics-enhanced neural network for phase retrieval from two diffraction patterns
  Opt. Express 30(18), 32680 (2022).
• L. Huang, H. Chen, T. Liu, and A. Ozcan
  GedankenNet: Self-supervised learning of hologram reconstruction using physics consistency
  Preprint at arXiv (2022).
• L. Bouchama, B. Dorizzi, J. Klossa, and Y. Gottesman
  A physics-inspired deep learning framework for an efficient FPM reconstruction under low overlap conditions
  Preprint at arXiv (2023).

Physics-connect-network (PcN) strategy

• Y. Rivenson, Y. Zhang, H. Günaydın, D. Teng, and A. Ozcan
  Phase recovery and holographic image reconstruction using deep learning in neural networks
  Light Sci Appl 7(2), 17141 (2018).
• Y. Wu, Y. Rivenson, Y. Zhang, Z. Wei, H. Günaydin, X. Lin, and A. Ozcan
  Extended depth-of-field in holographic imaging using deep-learning-based autofocusing and phase recovery
  Optica 5(6), 704 (2018).
• Goy et al., Phys. Rev. Lett. 2018, Low Photon Count Phase Retrieval Using Deep Learning
• J. Zhang, T. Xu, Z. Shen, Y. Qiao, and Y. Zhang
  Fourier ptychographic microscopy reconstruction with multiscale deep residual network
  Opt. Express 27(6), 8612 (2019).
• M. Deng, A. Goy, S. Li, K. Arthur, and G. Barbastathis
  Probing shallower: perceptual loss trained Phase Extraction Neural Network (PLT-PhENN) for artifact-free reconstruction at low photon budget
  Opt. Express 28(2), 2511 (2020).
• M. Deng, S. Li, A. Goy, I. Kang, and G. Barbastathis
  Learning to synthesize: robust phase retrieval at low photon counts
  Light Sci Appl 9(1), 36 (2020).
• I. Kang, F. Zhang, and G. Barbastathis
  Phase extraction neural network (PhENN) with coherent modulation imaging (CMI) for phase retrieval at low photon counts
  Opt. Express 28(15), 21578 (2020).
• I. Moon, K. Jaferzadeh, Y. Kim, and B. Javidi
  Noise-free quantitative phase imaging in Gabor holography with conditional generative adversarial network
  Opt. Express 28(18), 26284 (2020).
• Huang et al., ACS Photonics 2021,
  Holographic Image Reconstruction with Phase Recovery and Autofocusing Using Recurrent Neural Networks

Network-in-physics (NiP) strategy

(trained networks as denoiser regularization)

• C. A. Metzler, P. Schniter, A. Veeraraghavan, and R. G. Baraniuk
  prDeep: Robust Phase Retrieval with a Flexible Deep Network
  Preprint at arXiv (2018).
• Ç. Işıl, F. S. Oktem, and A. Koç
  Deep iterative reconstruction for phase retrieval
  Appl. Opt. 58(20), 5422 (2019).
• Z. Wu, Y. Sun, J. Liu, and U. Kamilov
  Online Regularization by Denoising with Applications to Phase Retrieval
  in 2019 IEEE/CVF International Conference on Computer Vision Workshop (ICCVW) (IEEE, 2019), pp. 3887–3895.
• C. Bai, M. Zhou, J. Min, S. Dang, X. Yu, P. Zhang, T. Peng, and B. Yao
  Robust contrast-transfer-function phase retrieval via flexible deep learning networks
  Opt. Lett. 44(21), 5141 (2019).
• Y. Wang, X. Sun, and J. W. Fleischer
  When deep denoising meets iterative phase retrieval
  Preprint at arXiv (2020).
• X. Chang, L. Bian, and J. Zhang
  Large-scale phase retrieval
  eLight 1(1), 4 (2021).
• S. Kumar
  Phase retrieval with physics informed zero-shot network
  Opt. Lett. 46(23), 5942 (2021).

(untrained networks as structural-prior regularization)

• G. Jagatap and C. Hegde
  Phase Retrieval using Untrained Neural Network Priors
  in NeurIPS 2019 Workshop on Solving Inverse Problems with Deep Networks (2019).
• G. Jagatap and C. Hegde
  Algorithmic Guarantees for Inverse Imaging with Untrained Network Priors
  in Advances in Neural Information Processing Systems 32 (2019).
• K. C. Zhou and R. Horstmeyer
  Diffraction tomography with a deep image prior
  Opt. Express 28(9), 12872 (2020).
• F. Shamshad, A. Hanif, and A. Ahmed
  Subsampled Fourier Ptychography using Pretrained Invertible and Untrained Network Priors
  Preprint at arXiv (2020).
• E. Bostan, R. Heckel, M. Chen, M. Kellman, and L. Waller
  Deep phase decoder: self-calibrating phase microscopy with an untrained deep neural network
  Optica 7(6), 559 (2020).
• H. Lawrence, D. A. Barmherzig, H. Li, M. Eickenberg, and M. Gabrié
  Phase Retrieval with Holography and Untrained Priors: Tackling the Challenges of Low-Photon Nanoscale Imaging
  Preprint at arXiv (2021).
• F. Niknam, H. Qazvini, and H. Latifi
  Holographic optical field recovery using a regularized untrained deep decoder network
  Sci Rep 11(1), 10903 (2021).
• L. Ma, H. Wang, N. Leng, and Z. Yuan
  ADMM based Fourier phase retrieval with untrained generative prior
  Preprint at arXiv (2022)
• Q. Chen, D. Huang, and R. Chen
  Fourier ptychographic microscopy with untrained deep neural network priors
  Opt. Express 30(22), 39597 (2022).

(trained networks as generative-prior regularization)

• P. Hand, O. Leong, and V. Voroninski
  Phase Retrieval Under a Generative Prior
  in Advances in Neural Information Processing Systems 31 (2018).
• F. Shamshad and A. Ahmed
  Robust Compressive Phase Retrieval via Deep Generative Priors
  Preprint at arXiv (2018).
• R. Hyder, V. Shah, C. Hegde, and M. S. Asif
  Alternating Phase Projected Gradient Descent with Generative Priors for Solving Compressive Phase Retrieval
  in ICASSP 2019 - 2019 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) (IEEE, 2019), pp. 7705–7709.
• F. Shamshad, F. Abbas, and A. Ahmed
  Deep Ptych: Subsampled Fourier Ptychography Using Generative Priors
  in ICASSP 2019 - 2019 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) (IEEE, 2019), pp. 7720–7724.
• F. Shamshad and A. Ahmed
  Compressed Sensing-Based Robust Phase Retrieval via Deep Generative Priors
  IEEE Sensors J. 21(2), 2286–2298 (2021).
• T. Uelwer, S. Konietzny, and S. Harmeling
  Optimizing Intermediate Representations of Generative Models for Phase Retrieval
  Preprint at arXiv (2022).

Physics-in-network (PiN) strategy

• C.-J. Wang, C.-K. Wen, S.-H. Tsai, and S. Jin
  Phase Retrieval With Learning Unfolded Expectation Consistent Signal Recovery Algorithm
  IEEE Signal Process. Lett. 27, 780–784 (2020).
• N. Naimipour, S. Khobahi, and M. Soltanalian
  UPR: A Model-Driven Architecture for Deep Phase Retrieval
  in 2020 54th Asilomar Conference on Signals, Systems, and Computers (IEEE, 2020), pp. 205–209.
• N. Naimipour, S. Khobahi, and M. Soltanalian
  Unfolded Algorithms for Deep Phase Retrieval
  Preprint at arXiv (2020).
• F. Zhang, X. Liu, C. Guo, S. Lin, J. Jiang, and X. Ji
  Physics-based Iterative Projection Complex Neural Network for Phase Retrieval in Lensless Microscopy Imaging
  in 2021 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR) (IEEE, 2021), pp. 10518–10526.
• B. Shi, Y. Gao, K. Jiang, and Q. Lian.
  Convolutional Sparse Coding with Weighted L1 Norm for Phase Retrieval: Algorithm and Its Deep Unfolded Network
  in 2022 IEEE International Conference on Image Processing (ICIP) (IEEE, 2022), pp. 1746–1750.
• X. Wu, Z. Wu, S. C. Shanmugavel, H. Z. Yu, and Y. Zhu
  Physics-informed neural network for phase imaging based on transport of intensity equation
  Opt. Express 30(24), 43398 (2022).
• Y. Yang, Q. Lian, X. Zhang, D. Zhang, and H. Zhang
  HIONet: Deep priors based deep unfolded network for phase retrieval
  Digital Signal Processing 132, 103797 (2022).

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DL-post-processing for phase recovery

Noise reduction

• W. Jeon, W. Jeong, K. Son, and H. Yang
  Speckle noise reduction for digital holographic images using multi-scale convolutional neural networks
  Opt. Lett. 43(17), 4240 (2018).
• G. Choi, D. Ryu, Y. Jo, Y. S. Kim, W. Park, H. Min, and Y. Park
  Cycle-consistent deep learning approach to coherent noise reduction in optical diffraction tomography
  Opt. Express 27(4), 4927 (2019).
• J. Zhang, X. Tian, J. Shao, H. Luo, and R. Liang
  Phase unwrapping in optical metrology via denoised and convolutional segmentation networks
  Opt. Express 27(10), 14903 (2019).
• K. Yan, Y. Yu, T. Sun, A. Asundi, and Q. Kemao
  Wrapped phase denoising using convolutional neural networks
  Optics and Lasers in Engineering 128, 105999 (2020).
• S. Montresor, M. Tahon, A. Laurent, and P. Picart
  Computational de-noising based on deep learning for phase data in digital holographic interferometry
  APL Photonics 5(3), 030802 (2020).
• K. Yan, L. Chang, M. Andrianakis, V. Tornari, and Y. Yu
  Deep Learning-Based Wrapped Phase Denoising Method for Application in Digital Holographic Speckle Pattern Interferometry
  Applied Sciences 10(11), 4044 (2020).
• M. Tahon, S. Montresor, and P. Picart
  Towards Reduced CNNs for De-Noising Phase Images Corrupted with Speckle Noise
  Photonics 8(7), 255 (2021).
• Q. Fang, H. Xia, Q. Song, M. Zhang, R. Guo, S. Montresor, and P. Picart
  Speckle denoising based on deep learning via a conditional generative adversarial network in digital holographic interferometry
  Opt. Express 30(12), 20666 (2022).
• M. Tahon, S. Montrésor, and P. Picart
  Deep Learning Network for Speckle De-Noising in Severe Conditions
  J. Imaging 8(6), 165 (2022).
• G. Murdaca, A. Rucci, and C. Prati
  Deep Learning for InSAR Phase Filtering: An Optimized Framework for Phase Unwrapping
  Remote Sensing 14(19), 4956 (2022).

Resolution enhancement

• T. Liu, K. de Haan, Y. Rivenson, Z. Wei, X. Zeng, Y. Zhang, and A. Ozcan
  Deep learning-based super-resolution in coherent imaging systems
  Sci Rep 9(1), 3926 (2019).
• J. Lim, A. B. Ayoub, and D. Psaltis
  Three-dimensional tomography of red blood cells using deep learning
  Adv. Photon. 2(02), 1 (2020).
• A. Butola, S. R. Kanade, S. Bhatt, V. K. Dubey, A. Kumar, A. Ahmad, D. K. Prasad, P. Senthilkumaran, B. S. Ahluwalia, and D. S. Mehta
  High space-bandwidth in quantitative phase imaging using partially spatially coherent digital holographic microscopy and a deep neural network
  Opt. Express 28(24), 36229 (2020).
• Y. Jiao, Y. R. He, M. E. Kandel, X. Liu, W. Lu, and G. Popescu
  Computational interference microscopy enabled by deep learning
  APL Photonics 6(4), 046103 (2021).
• D. Ryu, D. Ryu, Y. Baek, H. Cho, G. Kim, Y. S. Kim, Y. Lee, Y. Kim, J. C. Ye, H.-S. Min, and Y. Park
  DeepRegularizer: Rapid Resolution Enhancement of Tomographic Imaging Using Deep Learning
  IEEE Trans. Med. Imaging 40(5), 1508–1518 (2021).
• Z. Meng, G. Pedrini, X. Lv, J. Ma, S. Nie, and C. Yuan
  DL-SI-DHM: a deep network generating the high-resolution phase and amplitude images from wide-field images
  Opt. Express 29(13), 19247 (2021).
• A.-C. Li, S. Vyas, Y.-H. Lin, Y.-Y. Huang, H.-M. Huang, and Y. Luo
  Patch-Based U-Net Model for Isotropic Quantitative Differential Phase Contrast Imaging
  IEEE Trans. Med. Imaging 40(11), 3229–3237 (2021).
• R. K. Gupta, N. Hempler, G. P. A. Malcolm, K. Dholakia, and S. J. Powis
  High throughput hemogram of T cells using digital holographic microscopy and deep learning
  Opt. Continuum 2(3), 670 (2023).

Aberration correction

• T. Nguyen, V. Bui, V. Lam, C. B. Raub, L.-C. Chang, and G. Nehmetallah
  Automatic phase aberration compensation for digital holographic microscopy based on deep learning background detection
  Opt. Express 25(13), 15043 (2017).
• G. Zhang, T. Guan, Z. Shen, X. Wang, T. Hu, D. Wang, Y. He, and N. Xie
  Fast phase retrieval in off-axis digital holographic microscopy through deep learning
  Opt. Express 26(15), 19388 (2018).
• W. Xiao, L. Xin, R. Cao, X. Wu, R. Tian, L. Che, L. Sun, P. Ferraro, and F. Pan
  Sensing morphogenesis of bone cells under microfluidic shear stress by holographic microscopy and automatic aberration compensation with deep learning
  Lab Chip 21(7), 1385–1394 (2021).
• S. Ma, R. Fang, Y. Luo, Q. Liu, S. Wang, and X. Zhou
  Phase-aberration compensation via deep learning in digital holographic microscopy
  Meas. Sci. Technol. 32(10), 105203 (2021).
• L.-C. Lin, C.-H. Huang, Y.-F. Chen, D. Chu, and C.-J. Cheng
  Deep learning-assisted wavefront correction with sparse data for holographic tomography
  Optics and Lasers in Engineering 154, 107010 (2022).

Phase unwrapping

(Deep-learning-performed regression method, dRG)

• G. Dardikman and N. T. Shaked
  Phase Unwrapping Using Residual Neural Networks
  in Imaging and Applied Optics 2018 (3D, AO, AIO, COSI, DH, IS, LACSEA, LS&C, MATH, PcAOP) (OSA, 2018), p. CW3B.5.
• G. Dardikman, N. A. Turko, and N. T. Shaked
  Deep learning approaches for unwrapping phase images with steep spatial gradients: a simulation
  in 2018 IEEE International Conference on the Science of Electrical Engineering in Israel (ICSEE) (IEEE, 2018), pp. 1–4.
• K. Wang, Y. Li, Q. Kemao, J. Di, and J. Zhao
  One-step robust deep learning phase unwrapping
  Opt. Express 27(10), 15100 (2019).
• J. J. He, C. Sandino, D. Zeng, S. Vasanawala, and J. Cheng
  Deep spatiotemporal phase unwrapping of phase-contrast MRI data
  in Proceedings of the 27th ISMRM Annual Meeting & Exhibition, Montréal, QC, Canada (2019), pp. 11–16.
• K. Ryu, S.-M. Gho, Y. Nam, K. Koch, and D.-H. Kim
  Development of a deep learning method for phase unwrapping MR images
  in Proc. Intl. Soc. Mag. Reson. Med. (2019), 27, p. ,4707.
• G. Dardikman, D. Roitshtain, S. K. Mirsky, N. A. Turko, M. Habaza, and N. T. Shaked
  PhUn-Net: ready-to-use neural network for unwrapping quantitative phase images of biological cells
  Biomed. Opt. Express 11(2), 1107 (2020).
• Y. Qin, S. Wan, Y. Wan, J. Weng, W. Liu, and Q. Gong
  Direct and accurate phase unwrapping with deep neural network
  Appl. Opt. 59(24), 7258 (2020).
• M. V. Perera and A. De Silva
  A Joint Convolutional and Spatial Quad-Directional LSTM Network for Phase Unwrapping
  in IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) (2021), pp. 4055–4059.
• H. Zhou, C. Cheng, H. Peng, D. Liang, X. Liu, H. Zheng, and C. Zou
  The PHU‐NET: A robust phase unwrapping method for MRI based on deep learning
  Magn Reson Med 86(6), 3321–3333 (2021).
• S. Park, Y. Kim, and I. Moon
  Automated phase unwrapping in digital holography with deep learning
  Biomed. Opt. Express 12(11), 7064 (2021).
• L. Zhou, H. Yu, V. Pascazio, and M. Xing
  PU-GAN: A One-Step 2-D InSAR Phase Unwrapping Based on Conditional Generative Adversarial Network
  IEEE Trans. Geosci. Remote Sensing 60, 1–10 (2022).
• M. Xu, C. Tang, Y. Shen, N. Hong, and Z. Lei
  PU-M-Net for phase unwrapping with speckle reduction and structure protection in ESPI
  Optics and Lasers in Engineering 151, 106824 (2022).
• X. Xie, X. Tian, Z. Shou, Q. Zeng, G. Wang, Q. Huang, M. Qin, and X. Gao
  Deep learning phase-unwrapping method based on adaptive noise evaluation
  Appl. Opt. 61(23), 6861 (2022).
• J. Zhao, L. Liu, T. Wang, X. Wang, X. Du, R. Hao, J. Liu, Y. Liu, and J. Zhang
  VDE-Net: a two-stage deep learning method for phase unwrapping
  Opt. Express 30(22), 39794 (2022).

(Deep-learning-performed wrap count method, dWC)

• G. E. Spoorthi, S. Gorthi, and R. K. S. S. Gorthi
  PhaseNet: A Deep Convolutional Neural Network for Two-Dimensional Phase Unwrapping
  IEEE Signal Process. Lett. 26(1), 54–58 (2018).
• G. Dardikman, N. A. Turko, and N. T. Shaked
  Deep learning approaches for unwrapping phase images with steep spatial gradients: a simulation
  in 2018 IEEE International Conference on the Science of Electrical Engineering in Israel (ICSEE) (IEEE, 2018), pp. 1–4.
• J. Zhang, X. Tian, J. Shao, H. Luo, and R. Liang
  Phase unwrapping in optical metrology via denoised and convolutional segmentation networks
  Opt. Express 27(10), 14903 (2019).
• T. Zhang, S. Jiang, Z. Zhao, K. Dixit, X. Zhou, J. Hou, Y. Zhang, and C. Yan
  Rapid and robust two-dimensional phase unwrapping via deep learning
  Opt. Express 27(16), 23173 (2019).
• G. E. Spoorthi, R. K. Sai Subrahmanyam Gorthi, and S. Gorthi
  PhaseNet 2.0: Phase Unwrapping of Noisy Data Based on Deep Learning Approach
  IEEE Trans. on Image Process. 29, 4862–4872 (2020).
• C. Wu, Z. Qiao, N. Zhang, X. Li, J. Fan, H. Song, D. Ai, J. Yang, and Y. Huang
  Phase unwrapping based on a residual en-decoder network for phase images in Fourier domain Doppler optical coherence tomography
  Biomed. Opt. Express 11(4), 1760 (2020).
• Z. Zhao, B. Li, X. Kang, J. Lu, and T. Liu
  Phase unwrapping method for point diffraction interferometer based on residual auto encoder neural network
  Optics and Lasers in Engineering 138, 106405 (2020).
• S. Zhu, Z. Zang, X. Wang, Y. Wang, X. Wang, and D. Liu
  Phase unwrapping in ICF target interferometric measurement via deep learning
  Appl. Opt. 60(1), 10 (2021).
• K. S. Vengala, N. Paluru, and R. K. S. Subrahmanyam Gorthi
  3D deformation measurement in digital holographic interferometry using a multitask deep learning architecture
  J. Opt. Soc. Am. A 39(1), 167 (2022).
• K. S. Vengala, V. Ravi, and G. R. K. Sai Subrahmanyam
  A Multi-task Learning for 2D Phase Unwrapping in Fringe Projection
  IEEE Signal Process. Lett. 29, 797–801 (2022).
• J. Zhang and Q. Li
  EESANet: edge-enhanced self-attention network for two-dimensional phase unwrapping
  Opt. Express 30(7), 10470 (2022).
• W. Huang, X. Mei, Y. Wang, Z. Fan, C. Chen, and G. Jiang
  Two-dimensional phase unwrapping by a high-resolution deep learning network
  Measurement 200, 111566 (2022).
• Y. Wang, C. Zhou, and X. Qi
  PEENet for phase unwrapping in fringe projection profilometry
  in Thirteenth International Conference on Information Optics and Photonics (CIOP 2022), Y. Yang, ed. (SPIE, 2022), p. 163.

(Deep-learning-assisted method, dAS)

• W. Schwartzkopf, T. E. Milner, J. Ghosh, B. L. Evans, and A. C. Bovik
  Two-dimensional phase unwrapping using neural networks
  in 4th IEEE Southwest Symposium on Image Analysis and Interpretation (IEEE Comput. Soc, 2000), pp. 274–277.
• L. Zhou, H. Yu, and Y. Lan
  Deep Convolutional Neural Network-Based Robust Phase Gradient Estimation for Two-Dimensional Phase Unwrapping Using SAR Interferograms
  IEEE Trans. Geosci. Remote Sensing 58(7), 4653–4665 (2020).
• F. Sica, F. Calvanese, G. Scarpa, and P. Rizzoli
  A CNN-Based Coherence-Driven Approach for InSAR Phase Unwrapping
  IEEE Geosci. Remote Sensing Lett. 19, 1–5 (2020).
• Z. Wu, T. Wang, Y. Wang, and D. Ge
  A New Phase Unwrapping Method Combining Minimum Cost Flow with Deep Learning
  in 2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS (IEEE, 2021), pp. 3177–3180.
• H. Wang, J. Hu, H. Fu, C. Wang, and Z. Wang
  A Novel Quality-Guided Two-Dimensional InSAR Phase Unwrapping Method via GAUNet
  IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing 14, 7840–7856 (2021).
• L. Zhou, H. Yu, Y. Lan, and M. Xing
  Deep Learning-Based Branch-Cut Method for InSAR Two-Dimensional Phase Unwrapping
  IEEE Trans. Geosci. Remote Sensing 60, 1–15 (2021).
• Z. Wu, T. Wang, Y. Wang, R. Wang, and D. Ge
  Deep-Learning-Based Phase Discontinuity Prediction for 2-D Phase Unwrapping of SAR Interferograms
  IEEE Trans. Geosci. Remote Sensing 60, 1–16 (2021).
• L. Li, H. Zhang, Y. Tang, C. Wang, and F. Gu
  InSAR Phase Unwrapping by Deep Learning Based on Gradient Information Fusion
  IEEE Geosci. Remote Sensing Lett. 19, 1–5 (2021).

Back to Top

Deep learning for phase processing

Segmentation

• T. H. Nguyen, S. Sridharan, V. Macias, A. Kajdacsy-Balla, J. Melamed, M. N. Do, and G. Popescu
  Automatic Gleason grading of prostate cancer using quantitative phase imaging and machine learning
  J. Biomed. Opt 22(3), 036015 (2017).
• F. Yi, I. Moon, and B. Javidi
  Automated red blood cells extraction from holographic images using fully convolutional neural networks
  Biomed. Opt. Express 8(10), 4466 (2017).
• J. Lee, H. Kim, H. Cho, Y. Jo, Y. Song, D. Ahn, K. Lee, Y. Park, and S.-J. Ye
  Deep-Learning-Based Label-Free Segmentation of Cell Nuclei in Time-Lapse Refractive Index Tomograms
  IEEE Access 7, 83449–83460 (2019).
• E. Ahmadzadeh, K. Jaferzadeh, S. Shin, and I. Moon
  Automated single cardiomyocyte characterization by nucleus extraction from dynamic holographic images using a fully convolutional neural network
  Biomed. Opt. Express 11(3), 1501 (2020).
• M. E. Kandel, M. Rubessa, Y. R. He, S. Schreiber, S. Meyers, L. Matter Naves, M. K. Sermersheim, G. S. Sell, M. J. Szewczyk, N. Sobh, M. B. Wheeler, and G. Popescu
  Reproductive outcomes predicted by phase imaging with computational specificity of spermatozoon ultrastructure
  Proc. Natl. Acad. Sci. U.S.A. 117(31), 18302–18309 (2020).
• M. Lee, Y.-H. Lee, J. Song, G. Kim, Y. Jo, H. Min, C. H. Kim, and Y. Park
  Deep-learning-based three-dimensional label-free tracking and analysis of immunological synapses of CAR-T cells
  eLife 9, e49023 (2020).
• J. Choi, H.-J. Kim, G. Sim, S. Lee, W. S. Park, J. H. Park, H.-Y. Kang, M. Lee, W. D. Heo, J. Choo, H. Min, and Y. Park
  Label-free three-dimensional analyses of live cells with deep-learning-based segmentation exploiting refractive index distributions
  Preprint at bioRxiv (2021).
• N. Goswami, Y. R. He, Y.-H. Deng, C. Oh, N. Sobh, E. Valera, R. Bashir, N. Ismail, H. Kong, T. H. Nguyen, C. Best-Popescu, and G. Popescu
  Label-free SARS-CoV-2 detection and classification using phase imaging with computational specificity
  Light Sci. Appl. 10(1), 176 (2021).
• C. Hu, S. He, Y. J. Lee, Y. He, E. M. Kong, H. Li, M. A. Anastasio, and G. Popescu
  Live-dead assay on unlabeled cells using phase imaging with computational specificity
  Nat. Commun. 13(1), 713 (2022).
• J. K. Zhang, M. Fanous, N. Sobh, A. Kajdacsy-Balla, and G. Popescu
  Automatic Colorectal Cancer Screening Using Deep Learning in Spatial Light Interference Microscopy Data
  Cells 11(4), 716 (2022).
• Y. R. He, S. He, M. E. Kandel, Y. J. Lee, C. Hu, N. Sobh, M. A. Anastasio, and G. Popescu
  Cell Cycle Stage Classification Using Phase Imaging with Computational Specificity
  ACS Photonics 9(4), 1264–1273 (2022).
• S. Jiang, C. Guo, P. Song, T. Wang, R. Wang, T. Zhang, Q. Wu, R. Pandey, and G. Zheng
  High-throughput digital pathology via a handheld, multiplexed, and AI-powered ptychographic whole slide scanner
  Lab. Chip 22(14), 2657–2670 (2022).

Classification

(via conventional machine learning)

• C. L. Chen, A. Mahjoubfar, L.-C. Tai, I. K. Blaby, A. Huang, K. R. Niazi, and B. Jalali
  Deep Learning in Label-free Cell Classification
  Sci Rep 6(1), 21471 (2016).
• D. Roitshtain, L. Wolbromsky, E. Bal, H. Greenspan, L. L. Satterwhite, and N. T. Shaked
  Quantitative phase microscopy spatial signatures of cancer cells
  Cytometry 91(5), 482–493 (2017).
• J. Yoon, Y. Jo, M. Kim, K. Kim, S. Lee, S.-J. Kang, and Y. Park
  Identification of non-activated lymphocytes using three-dimensional refractive index tomography and machine learning
  Sci Rep 7(1), 6654 (2017).
• S. K. Mirsky, I. Barnea, M. Levi, H. Greenspan, and N. T. Shaked
  Automated analysis of individual sperm cells using stain-free interferometric phase microscopy and machine learning: Sperm Analysis Using Interferometry and Machine Learning
  Cytometry 91(9), 893–900 (2017).
• Y. Li, B. Cornelis, A. Dusa, G. Vanmeerbeeck, D. Vercruysse, E. Sohn, K. Blaszkiewicz, D. Prodanov, P. Schelkens, and L. Lagae
  Accurate label-free 3-part leukocyte recognition with single cell lens-free imaging flow cytometry
  Computers in Biology and Medicine 96, 147–156 (2018).
• B. Javidi, A. Markman, S. Rawat, T. O’Connor, A. Anand, and B. Andemariam
  Sickle cell disease diagnosis based on spatio-temporal cell dynamics analysis using 3D printed shearing digital holographic microscopy
  Opt. Express 26(10), 13614 (2018).
• G. Kim, Y. Jo, H. Cho, H. Min, and Y. Park
  Learning-based screening of hematologic disorders using quantitative phase imaging of individual red blood cells
  Biosensors and Bioelectronics 123, 69–76 (2019).
• Y. Ozaki, H. Yamada, H. Kikuchi, A. Hirotsu, T. Murakami, T. Matsumoto, T. Kawabata, Y. Hiramatsu, K. Kamiya, T. Yamauchi, K. Goto, Y. Ueda, S. Okazaki, M. Kitagawa, H. Takeuchi, and H. Konno
  Label-free classification of cells based on supervised machine learning of subcellular structures
  PLoS ONE 14(1), e0211347 (2019).
• V. Bianco, P. Memmolo, P. Carcagnì, F. Merola, M. Paturzo, C. Distante, and P. Ferraro
  Microplastic Identification via Holographic Imaging and Machine Learning
  Advanced Intelligent Systems 2(2), 1900153 (2020).
• A. V. Belashov, A. A. Zhikhoreva, T. N. Belyaeva, E. S. Kornilova, A. V. Salova, I. V. Semenova, and O. S. Vasyutinskii
  In vitro monitoring of photoinduced necrosis in HeLa cells using digital holographic microscopy and machine learning
  J. Opt. Soc. Am. A 37(2), 346 (2020).
• V. K. Lam, T. C. Nguyen, V. Bui, B. M. Chung, L.-C. Chang, G. Nehmetallah, and C. B. Raub
  Quantitative scoring of epithelial and mesenchymal qualities of cancer cells using machine learning and quantitative phase imaging
  J. Biomed. Opt. 25(02), 026002–026002 (2020).
• S. Park, J. W. Ahn, Y. Jo, H.-Y. Kang, H. J. Kim, Y. Cheon, J. W. Kim, Y. Park, S. Lee, and K. Park
  Label-Free Tomographic Imaging of Lipid Droplets in Foam Cells for Machine-Learning-Assisted Therapeutic Evaluation of Targeted Nanodrugs
  ACS Nano 14(2), 1856–1865 (2020).
• N. Nissim, M. Dudaie, I. Barnea, and N. T. Shaked
  Real‐Time Stain‐Free Classification of Cancer Cells and Blood Cells Using Interferometric Phase Microscopy and Machine Learning
  Cytometry 99(5), 511–523 (2021).
• V. Bianco, D. Pirone, P. Memmolo, F. Merola, and P. Ferraro
  Identification of Microplastics Based on the Fractal Properties of Their Holographic Fingerprint
  ACS Photonics 8(7), 2148–2157 (2021).
• S. K. Paidi, P. Raj, R. Bordett, C. Zhang, S. H. Karandikar, R. Pandey, and I. Barman
  Raman and quantitative phase imaging allow morpho-molecular recognition of malignancy and stages of B-cell acute lymphoblastic leukemia
  Biosensors and Bioelectronics 190, 113403 (2021).
• P. Memmolo, G. Aprea, V. Bianco, R. Russo, I. Andolfo, M. Mugnano, F. Merola, L. Miccio, A. Iolascon, and P. Ferraro
  Differential diagnosis of hereditary anemias from a fraction of blood drop by digital holography and hierarchical machine learning
  Biosensors and Bioelectronics 201, 113945 (2022).
• M. Valentino, J. Bĕhal, V. Bianco, S. Itri, R. Mossotti, G. D. Fontana, T. Battistini, E. Stella, L. Miccio, and P. Ferraro
  Intelligent polarization-sensitive holographic flow-cytometer: Towards specificity in classifying natural and microplastic fibers
  Science of The Total Environment 815, 152708 (2022).
• D. Pirone, L. Xin, V. Bianco, L. Miccio, W. Xiao, L. Che, X. Li, P. Memmolo, F. Pan, and P. Ferraro
  Identification of drug-resistant cancer cells in flow cytometry combining 3D holographic tomography with machine learning
  Sensors and Actuators B: Chemical 375, 132963 (2023).

(via deep learning with only phase as input)

• Y. Jo, S. Park, J. Jung, J. Yoon, H. Joo, M. Kim, S.-J. Kang, M. C. Choi, S. Y. Lee, and Y. Park
  Holographic deep learning for rapid optical screening of anthrax spores
  Sci. Adv. 3(8), e1700606 (2017).
• S. H. Karandikar, C. Zhang, A. Meiyappan, I. Barman, C. Finck, P. K. Srivastava, and R. Pandey
  Reagent-Free and Rapid Assessment of T Cell Activation State Using Diffraction Phase Microscopy and Deep Learning
  Anal. Chem. 91(5), 3405–3411 (2019).
• M. Rubin
  TOP-GAN: Stain-free cancer cell classification using deep learning with a small training set
  Medical Image Analysis 57, 176–185 (2019).
• J. K. Zhang, Y. R. He, and N. Sobh
  Label-free colorectal cancer screening using deep learning and spatial light interference microscopy (SLIM)
  APL Photonics 5(4), 040805 (2020).
• A. Butola, D. Popova, D. K. Prasad, A. Ahmad, A. Habib, J. C. Tinguely, P. Basnet, G. Acharya, P. Senthilkumaran, D. S. Mehta, and B. S. Ahluwalia
  High spatially sensitive quantitative phase imaging assisted with deep neural network for classification of human spermatozoa under stressed condition
  Sci Rep 10(1), 13118 (2020).
• Y. Li, J. Di, L. Ren, and J. Zhao
  Deep-learning-based prediction of living cells mitosis via quantitative phase microscopy
  Chin. Opt. Lett. 19(5), 051701 (2021).
• X. Shu, S. Sansare, D. Jin, X. Zeng, K.-Y. Tong, R. Pandey, and R. Zhou
  Artificial‐Intelligence‐Enabled Reagent‐Free Imaging Hematology Analyzer
  Advanced Intelligent Systems 3(8), 2000277 (2021).
• B. L. Reddy, R. N. Uma Mahesh, and A. Nelleri
  Deep convolutional neural network for three-dimensional objects classification using off-axis digital Fresnel holography
  Journal of Modern Optics 69(13), 705–717 (2022).

(via deep learning with phase and amplitude as input)

• T. Pitkäaho, A. Manninen, and T. J. Naughton
  Temporal Deep Learning Classification of Digital Hologram Reconstructions of Multicellular Samples
  in Biophotonics Congress: Biomedical Optics Congress 2018 (Microscopy/Translational/Brain/OTS) (OSA, 2018), p. JW3A.14.
• Y. Wu, A. Calis, Y. Luo, C. Chen, M. Lutton, Y. Rivenson, X. Lin, H. C. Koydemir, Y. Zhang, H. Wang, Z. Göröcs, and A. Ozcan
  Label-Free Bioaerosol Sensing Using Mobile Microscopy and Deep Learning
  ACS Photonics 5(11), 4617–4627 (2018).
• H. H. Lam, P. W. M. Tsang, and T.-C. Poon
  Ensemble convolutional neural network for classifying holograms of deformable objects
  Opt. Express 27(23), 34050 (2019).
• H. H. S. Lam, P. W. M. Tsang, and T.-C. Poon
  Hologram classification of occluded and deformable objects with speckle noise contamination by deep learning
  J. Opt. Soc. Am. A 39(3), 411 (2022).
• D. Terbe, L. Orzó, and Á. Zarándy
  Classification of Holograms with 3D-CNN
  Sensors 22(21), 8366 (2022).
• H. Lam, Y. Zhu, and P. Buranasiri
  Off-Axis Holographic Interferometer with Ensemble Deep Learning for Biological Tissues Identification
  Applied Sciences 12(24), 12674 (2022).

(via deep learning with multi-wavelength phase as input)

• N. Singla and V. Srivastava
  Deep learning enabled multi-wavelength spatial coherence microscope for the classification of malaria-infected stages with limited labelled data size
  Optics & Laser Technology 130, 106335 (2020).
• Ç. Işıl, K. de Haan, Z. Göröcs, H. C. Koydemir, S. Peterman, D. Baum, F. Song, T. Skandakumar, E. Gumustekin, and A. Ozcan
  Phenotypic Analysis of Microalgae Populations Using Label-Free Imaging Flow Cytometry and Deep Learning
  ACS Photonics 8(4), 1232–1242 (2021).

(via deep learning with multi-temporal-dimension phase as input)

• H. Wang, H. Ceylan Koydemir, Y. Qiu, B. Bai, Y. Zhang, Y. Jin, S. Tok, E. C. Yilmaz, E. Gumustekin, Y. Rivenson, and A. Ozcan
  Early detection and classification of live bacteria using time-lapse coherent imaging and deep learning
  Light Sci Appl 9(1), 118 (2020).
• S. Ben Baruch, N. Rotman-Nativ, A. Baram, H. Greenspan, and N. T. Shaked
  Cancer-Cell Deep-Learning Classification by Integrating Quantitative-Phase Spatial and Temporal Fluctuations
  Cells 10(12), 3353 (2021).
• T. Liu, Y. Li, H. C. Koydemir, Y. Zhang, E. Yang, H. Wang, J. Li, B. Bai, and A. Ozcan
  Stain-free, rapid, and quantitative viral plaque assay using deep learning and holography
  Preprint at arXiv (2022).

(via deep learning with 3D refractive index as input)

• D. Ryu, J. Kim, D. Lim, H.-S. Min, I. Y. Yoo, D. Cho, and Y. Park
  Label-Free White Blood Cell Classification Using Refractive Index Tomography and Deep Learning
  BME Front 2021, 2021/9893804 (2021).
• G. Kim, D. Ahn, M. Kang, J. Park, D. Ryu, Y. Jo, J. Song, J. S. Ryu, G. Choi, H. J. Chung, K. Kim, D. R. Chung, I. Y. Yoo, H. J. Huh, H. Min, N. Y. Lee, and Y. Park
  Rapid species identification of pathogenic bacteria from a minute quantity exploiting three-dimensional quantitative phase imaging and artificial neural network
  Light Sci Appl 11(1), 190 (2022).

(via deep learning with amplitude or hologram as input)

• S.-J. Kim, C. Wang, B. Zhao, H. Im, J. Min, H. J. Choi, J. Tadros, N. R. Choi, C. M. Castro, R. Weissleder, H. Lee, and K. Lee
  Deep transfer learning-based hologram classification for molecular diagnostics
  Sci Rep 8(1), 17003 (2018).
• Y. Zhu, C. Hang Yeung, and E. Y. Lam
  Digital holographic imaging and classification of microplastics using deep transfer learning
  Appl. Opt. 60(4), A38 (2021).
• M. Delli Priscoli, P. Memmolo, G. Ciaparrone, V. Bianco, F. Merola, L. Miccio, F. Bardozzo, D. Pirone, M. Mugnano, F. Cimmino, M. Capasso, A. Iolascon, P. Ferraro, and R. Tagliaferri
  Neuroblastoma Cells Classification Through Learning Approaches by Direct Analysis of Digital Holograms
  IEEE J. Select. Topics Quantum Electron. 27(5), 1–9 (2021).
• Y. Zhu, C. Hang Yeung, and E. Y. Lam
  Microplastic pollution monitoring with holographic classification and deep learning
  J. Phys. Photonics 3(2), 024013 (2021).
• D. Chen, Z. Wang, K. Chen, Q. Zeng, L. Wang, X. Xu, J. Liang, and X. Chen
  Classification of unlabeled cells using lensless digital holographic images and deep neural networks
  Quant Imaging Med Surg 11(9), 4137–4148 (2021).
• L. MacNeil, S. Missan, J. Luo, T. Trappenberg, and J. LaRoche
  Plankton classification with high-throughput submersible holographic microscopy and transfer learning
  BMC Ecol Evo 21(1), 123 (2021).
• Y. Zhu, H. K. A. Lo, C. H. Yeung, and E. Y. Lam
  Microplastic pollution assessment with digital holography and zero-shot learningt
  APL Photonics 7(7), 076102 (2022).

Imaging modal transformation

(Phase to bright-field or stained bright-field images)

• Y. Wu, Y. Luo, G. Chaudhari, Y. Rivenson, A. Calis, K. de Haan, and A. Ozcan
  Bright-field holography: cross-modality deep learning enables snapshot 3D imaging with bright-field contrast using a single hologram
  Light Sci Appl 8(1), 25 (2019).
• T. Liu, Z. Wei, Y. Rivenson, K. Haan, Y. Zhang, Y. Wu, and A. Ozcan
  Deep learning‐based color holographic microscopy
  J. Biophotonics 12(11), e201900107 (2019).
• Y. Rivenson, T. Liu, Z. Wei, Y. Zhang, K. de Haan, and A. Ozcan
  PhaseStain: the digital staining of label-free quantitative phase microscopy images using deep learning
  Light Sci Appl 8(1), 23 (2019).
• Y. N. Nygate, M. Levi, S. K. Mirsky, N. A. Turko, M. Rubin, I. Barnea, G. Dardikman-Yoffe, M. Haifler, A. Shalev, and N. T. Shaked
  Holographic virtual staining of individual biological cells
  Proc. Natl. Acad. Sci. U.S.A. 117(17), 9223–9231 (2020).
• R. Wang, P. Song, S. Jiang, C. Yan, J. Zhu, C. Guo, Z. Bian, T. Wang, and G. Zheng
  Virtual brightfield and fluorescence staining for Fourier ptychography via unsupervised deep learning
  Opt. Lett. 45(19), 5405 (2020).
• D. Terbe, L. Orzó, and Á. Zarándy
  Deep-learning-based bright-field image generation from a single hologram using an unpaired dataset Opt. Lett. 46(22), 5567 (2021).

(Phase to fluorescence images)

• S.-M. Guo, L.-H. Yeh, J. Folkesson, I. E. Ivanov, A. P. Krishnan, M. G. Keefe, E. Hashemi, D. Shin, B. B. Chhun, N. H. Cho, M. D. Leonetti, M. H. Han, T. J. Nowakowski, and S. B. Mehta
  Revealing architectural order with quantitative label-free imaging and deep learning
  eLife 9, e55502 (2020).
• M. E. Kandel, Y. R. He, Y. J. Lee, T. H.-Y. Chen, K. M. Sullivan, O. Aydin, M. T. A. Saif, H. Kong, N. Sobh, and G. Popescu
  Phase imaging with computational specificity (PICS) for measuring dry mass changes in sub-cellular compartments
  Nat Commun 11(1), 6256 (2020).
• M. E. Kandel, E. Kim, Y. J. Lee, G. Tracy, H. J. Chung, and G. Popescu
  Multiscale Assay of Unlabeled Neurite Dynamics Using Phase Imaging with Computational Specificity
  ACS Sens. 6(5), 1864–1874 (2021).
• S. Guo, Y. Ma, Y. Pan, Z. J. Smith, and K. Chu
  Organelle-specific phase contrast microscopy enables gentle monitoring and analysis of mitochondrial network dynamics
  Biomed. Opt. Express 12(7), 4363 (2021).
• X. Chen, M. E. Kandel, S. He, C. Hu, Y. J. Lee, K. Sullivan, G. Tracy, H. J. Chung, H. J. Kong, M. Anastasio, and G. Popescu
  Artificial confocal microscopy for deep label-free imaging
  Preprint at /arXiv (2021).
• X. Chen, M. E. Kandel, S. He, C. Hu, Y. J. Lee, K. Sullivan, G. Tracy, H. J. Chung, H. J. Kong, M. Anastasio, and G. Popescu
  Artificial confocal microscopy for deep label-free imaging
  Nat. Photon. 17(3), 250–258 (2023).

(3D refractive index to fluorescence images)

• Y. Jo, H. Cho, W. S. Park, G. Kim, D. Ryu, Y. S. Kim, M. Lee, S. Park, M. J. Lee, H. Joo, H. Jo, S. Lee, S. Lee, H. Min, W. D. Heo, and Y. Park
  Label-free multiplexed microtomography of endogenous subcellular dynamics using generalizable deep learning
  Nat Cell Biol 23(12), 1329–1337 (2021).

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Review/Tutorial papers

(In chronological order)

Conventional phase recovery

• Y. Shechtman, Y. C. Eldar, O. Cohen, H. N. Chapman, J. Miao, and M. Segev
  Phase Retrieval with Application to Optical Imaging: A contemporary overview,
  IEEE Signal Process. Mag. 32(3), 87–109 (2015).

• Y. Park, C. Depeursinge, and G. Popescu
  Quantitative phase imaging in biomedicine,
  Nature Photon. 12(10), 578–589 (2018).

• T. Latychevskaia
  Iterative phase retrieval for digital holography: tutorial,
  J. Opt. Soc. Am. A 36(12), D31 (2019).

• H. Yu, Y. Lan, Z. Yuan, J. Xu, and H. Lee
  Phase Unwrapping in InSAR: A Review,
  IEEE Geosci. Remote Sens. Mag. 7(1), 40–58 (2019).

• T. Cacace, V. Bianco, and P. Ferraro
  Quantitative phase imaging trends in biomedical applications,
  Optics and Lasers in Engineering 135, 106188 (2020).

• J. T. Sheridan, R. K. Kostuk, A. F. Gil, Y. Wang, W. Lu, H. Zhong, Y. Tomita, C. Neipp, J. Francés, S. Gallego, I. Pascual, V. Marinova, S.-H. Lin, K.-Y. Hsu, F. Bruder, S. Hansen, C. Manecke, R. Meisenheimer, C. Rewitz, T. Rölle, S. Odinokov, O. Matoba, M. Kumar, X. Quan, Y. Awatsuji, P. W. Wachulak, A. V. Gorelaya, A. A. Sevryugin, E. V. Shalymov, V. Yu Venediktov, R. Chmelik, M. A. Ferrara, G. Coppola, A. Márquez, A. Beléndez, W. Yang, R. Yuste, A. Bianco, A. Zanutta, C. Falldorf, J. J. Healy, X. Fan, B. M. Hennelly, I. Zhurminsky, M. Schnieper, R. Ferrini, S. Fricke, G. Situ, H. Wang, A. S. Abdurashitov, V. V. Tuchin, N. V. Petrov, T. Nomura, D. R. Morim, and K. Saravanamuttu
  Roadmap on holography,
  J. Opt. 22(12), 123002 (2020).

• C. Zuo, J. Li, J. Sun, Y. Fan, J. Zhang, L. Lu, R. Zhang, B. Wang, L. Huang, and Q. Chen
  Transport of intensity equation: a tutorial,
  Optics and Lasers in Engineering 106187 (2020).

• V. Balasubramani, M. Kujawińska, C. Allier, V. Anand, C.-J. Cheng, C. Depeursinge, N. Hai, S. Juodkazis, J. Kalkman, A. Kuś, M. Lee, P. J. Magistretti, P. Marquet, S. H. Ng, J. Rosen, Y. K. Park, and M. Ziemczonok
  Roadmap on Digital Holography-Based Quantitative Phase Imaging,
  J. Imaging 7(12), 252 (2021).

• B. Javidi, A. Carnicer, A. Anand, G. Barbastathis, W. Chen, P. Ferraro, J. W. Goodman, R. Horisaki, K. Khare, M. Kujawinska, R. A. Leitgeb, P. Marquet, T. Nomura, A. Ozcan, Y. Park, G. Pedrini, P. Picart, J. Rosen, G. Saavedra, N. T. Shaked, A. Stern, E. Tajahuerce, L. Tian, G. Wetzstein, and M. Yamaguchi
  Roadmap on digital holography [Invited],
  Opt. Express 29(22), 35078 (2021).

• G. Zheng, C. Shen, S. Jiang, P. Song, and C. Yang
  Concept, implementations and applications of Fourier ptychography,
  Nat. Rev. Phys. 3(3), 207–223 (2021).

• V. Petrov, A. Pogoda, V. Sementin, A. Sevryugin, E. Shalymov, D. Venediktov, and V. Venediktov
  Advances in Digital Holographic Interferometry,
  J. Imaging 8(7), 196 (2022).

• T. L. Nguyen, S. Pradeep, R. L. Judson-Torres, J. Reed, M. A. Teitell, and T. A. Zangle
  Quantitative Phase Imaging: Recent Advances and Expanding Potential in Biomedicine,
  ACS Nano 16(8), 11516–11544 (2022).

• G. Baffou
  Wavefront Microscopy Using Quadriwave Lateral Shearing Interferometry: From Bioimaging to Nanophotonics,
  ACS Photonics 10(2), 322–339 (2023).

Deep-learning-based phase recovery

• Y. Jo, H. Cho, S. Y. Lee, G. Choi, G. Kim, H. Min, and Y. Park
  Quantitative Phase Imaging and Artificial Intelligence: A Review,
  IEEE J. Select. Topics Quantum Electron. 25(1), 1–14 (2019).

• Y. Rivenson, Y. Wu, and A. Ozcan
  Deep learning in holography and coherent imaging,
  Light Sci. Appl. 8(1), 85 (2019).

• G. Ongie, A. Jalal, C. A. Metzler, R. G. Baraniuk, A. G. Dimakis, and R. Willett
  Deep Learning Techniques for Inverse Problems in Imaging,
  arXiv:2005.06001 (2020).

• T. Zeng, Y. Zhu, and E. Y. Lam
  Deep learning for digital holography: a review,
  Opt. Express 29(24), 40572 (2021).

• L. Zhou, H. Yu, Y. Lan, and M. Xing
  Artificial Intelligence In Interferometric Synthetic Aperture Radar Phase Unwrapping: A Review,
  IEEE Geosci. Remote Sens. Mag. 2–20 (2021).

• C. Zuo, J. Qian, S. Feng, W. Yin, Y. Li, P. Fan, J. Han, K. Qian, and Q. Chen
  Deep learning in optical metrology: a review,
  Light Sci. Appl. 11(1), 39 (2022).

• T. Shimobaba, D. Blinder, T. Birnbaum, I. Hoshi, H. Shiomi, P. Schelkens, and T. Ito
  Deep-Learning Computational Holography: A Review,
  Front. Photon. 3, 854391 (2022).

• G. Situ
  Deep holography,
  Light Advanced Manufacturing 3(2), 1 (2022).

• A. Qayyum, I. Ilahi, F. Shamshad, F. Boussaid, M. Bennamoun, and J. Qadir
  Untrained Neural Network Priors for Inverse Imaging Problems: A Survey,
  IEEE Trans. Pattern Anal. Mach. Intell. 45(5), 6511–6536 (2022).

• Y. Guo, L. Zhong, L. Min, J. Wang, Y. Wu, K. Chen, K. Wei, and C. Rao
  Adaptive optics based on machine learning: a review,
  Opto-Electronic Advances 5(7), 200082–200082 (2022).

• K. Wang, Q. Kemao, J. Di, and J. Zhao
  Deep learning spatial phase unwrapping: a comparative review,
  Adv. Photon. Nexus 1(1), 014001 (2022).

• J. Dong, L. Valzania, A. Maillard, T. Pham, S. Gigan, and M. Unser
  Phase Retrieval: From Computational Imaging to Machine Learning: A tutorial,
  IEEE Signal Process. Mag. 40(1), 45–57 (2023).

• J. Park, B. Bai, D. Ryu, T. Liu, C. Lee, Y. Luo, M. J. Lee, L. Huang, J. Shin, Y. Zhang, D. Ryu, Y. Li, G. Kim, H. Min, A. Ozcan, and Y. Park
  Artificial intelligence-enabled quantitative phase imaging methods for life sciences,
  Nat Methods 20, 1645–1660 (2023).

• K. Wang, L. Song, C. Wang, Z. Ren, G. Zhao, J. Dou, J. Di, G. Barbastathis, R. Zhou, J. Zhao, and E. Y. Lam
  On the use of deep learning for phase recover,
  Light Sci Appl 13(1), 4 (2024).

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Books

(In chronological order)

• D. C. Ghiglia and M. D. Pritt
  Two-Dimensional Phase Unwrapping: Theory, Algorithms, and Software,
  (Wiley, 1998).

• J. W. Goodman
  Introduction to Fourier Optics,
  3rd ed (Roberts & Co, 2005).

• E. H. Duke and S. R. Aguirre
  3D Imaging: Theory, Technology and Applications, Computer Science, Technology and Applications,
  (Nova Science Publishers, 2010).

• T. Tishko, D. Tishko, and V. P. Titar
  Holographic Microscopy of Phase Microscopic Objects: Theory and Practice,
  (World Scientific Publishing Co., 2011).

• M. Mir, B. Bhaduri, R. Wang, R. Zhu, and G. Popescu
  Quantitative Phase Imaging,
  in Progress in Optics (Elsevier, 2012), 57, pp. 133–217.

• Q. Kemao
  Windowed Fringe Pattern Analysis,
  (SPIE, 2013).

• B. Javidi, E. Tajahuerce, and P. Andres
  Multi-Dimensional Imaging,
  (Cambridge University Press, John Wiley & Sons Inc, 2014).

• T.-C. Poon and J.-P. Liu
  Introduction to Modern Digital Holography: With MATLAB,
  (Cambridge University Press, 2014).

• M. Servín, J. Antonio Quiroga, J. Moisés Padilla, J. A. Quiroga, J. M. Padilla, and J. M. Padilla
  Fringe Pattern Analysis for Optical Metrology: Theory, Algorithms, and Applications,
  (Wiley-VCH, 2014).

• C. Liu, S. Wang, and S. P. Veetil
  Computational Optical Phase Imaging, Progress in Optical Science and Photonics,
  (Springer Singapore, 2022), 21.

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Dissertations and Thesis

(In chronological order)

• George Barbastathis,
  Intelligent holographic databases,
  Ph.D. Thesis, California Institute of Technology, 1997. PDF

• Stephen A. Boppart,
  Surgical diagnostics, guidance, and intervention using optical coherence tomography,
  Ph.D. Thesis, Massachusetts Institute of Technology, 1998. PDF

• Changhuei Yang,
  Harmonic phase based low coherence interferometry : a method for studying the dynamics and structures of cells,
  Ph.D. Thesis, Massachusetts Institute of Technology, 2002. PDF

• Laura Waller,
  Computational phase imaging based on intensity transport,
  Ph.D. Thesis, Massachusetts Institute of Technology, 2010. PDF

• Guoan Zheng,
  Innovations in Imaging System Design: Gigapixel, Chip-Scale and MultiFunctional Microscopy,
  Ph.D. Thesis, California Institute of Technology, 2012. PDF

• YongKeun Park,
  Pathophysiology of human red blood cell probed by quantitative phase microscopy,
  Ph.D. Thesis, Massachusetts Institute of Technology, 2013. PDF

• Hoa Pham,
  Real-time quantitative phase imaging for cell studies,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2013. PDF

• Lei Tian,
  Compressive phase retrieval,
  Ph.D. Thesis, Massachusetts Institute of Technology, 2013. PDF

• Mustafa Mir,
  Quantitative phase imaging for cellular biology,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2013. PDF

• Renjie Zhou,
  Interferometric light microscopy for wafer defect inspection and three-dimensional object reconstruction,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2013. PDF

• Nathan D. Shemonski,
  In vivo human computed optical interferometric tomography,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2015. PDF

• Dennis J. Lee,
  Computational optical imaging: Applications in synthetic aperture imaging, phase retrieval, and digital holography,
  Ph.D. Thesis, Purdue University, 2015. PDF

• Tae-Woo Kim,
  Quantitative phase imaging: advances to 3D imaging and applications to neuroscience,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2015. PDF

• Chien-Hung Lu,
  Computational Phase Imaging in Nonlinear and Quantum Systems,
  Ph.D. Thesis, Princeton University, 2015. PDF

• Shamira Sridharan,
  Applications of quantitative phase imaging for pathology,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2015. PDF

• Tan Huu Nguyen,
  Computational phase imaging for biomedical applications,
  Ph.D. Thesis, University of Illinois at Urbana-Champaign, 2016. PDF

• Chandrabhan Seniya,
  A flexible low-cost quantitative phase imaging microscopy system for label-free imaging of multi-cellular biological samples,
  Ph.D. Thesis, University of Warwick, 2018. PDF

• Aamod Shanker,
  Differential methods in phase imaging for optical lithography,
  Ph.D. Thesis, University of California, Berkeley, 2018. PDF

• Shuai Li,
  Computational imaging through deep learning,
  Ph.D. Thesis, Massachusetts Institute of Technology, 2019. PDF

• David A. Barmherzig,
  The Phase Retrieval Problem: Theory, Algorithms, and Applications,
  Ph.D. Thesis, Stanford University, 2019. PDF

• Yichen Wu,
  Deep Learning-enabled Computational Imaging in Optical Microscopy and Air Quality Monitoring,
  Ph.D. Thesis, University of California, Los Angeles, 2019. PDF

• Michael Kellman,
  Physics-based Learning for Large-scale Computational Imaging,
  Ph.D. Thesis, University of California, Berkeley, 2020. PDF

• Zhuoqun Zhang,
  Analysis and Development of Phase Retrieval Algorithms for Ptychography,
  Ph.D. Thesis, University of Sheffield, 2021. PDF

• Baoliang Ge,
  Single-shot quantitative interferometric microscopy for imaging high-speed dynamics,
  Ph.D. Thesis, Massachusetts Institute of Technology, 2021. PDF

• Obed A. Ayisi,
  Multiple-Wavelength Phase Retrieval With Digital Holographic Microscopy,
  Masters Thesis, Northern Arizona University, 2021.

• Tairan Liu,
  Deep Learning in Optical Microscopy, Holographic Imaging and Sensing,
  Ph.D. Thesis, University of California, Los Angeles, 2022.

• Marissa A. Morado,
  Solving the phase retrieval problem using an artificial neural network,
  Ph.D. Thesis, California State University, Fresno, 2022. PDF

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