[1] J. X. Li, T. Y. Gan, B. J. Bai et al. Massively parallel universal linear transformations using a wavelength-multiplexed diffractive optical network. Adv. Photonics, 5, 016003(2023).

[2] L. P. Lu, J. J. Li, Y. F. Shu et al. Hybrid brightfield and darkfield transport of intensity approach for high-throughput quantitative phase microscopy. Adv. Photonics, 4, 056002(2022).

[3] Y. M. Xu, X. C. Pan, M. Sun et al. Single-shot ultrafast multiplexed coherent diffraction imaging. Photonics Res., 10, 1937(2022).

[4] A. Saba, C. Gigli, A. B. Ayoub et al. Physics-informed neural networks for diffraction tomography. Adv. Photonics, 4, 066001(2022).

[5] J. W. Miao, P. Charalambous, J. Kirz et al. Extending the methodology of X-ray crystallography to allow imaging of micrometre-sized non-crystalline specimens. Nature, 400, 342(1999).

[6] J. M. Miao, T. Ishikawa, I. K. Robinson et al. Beyond crystallography: diffractive imaging using coherent X-ray light sources. Science, 348, 530(2015).

[7] R. W. Gerchberg. A practical algorithm for the determination of phase from image and diffraction plane pictures. Optik, 35, 237(1972).

[8] W. O. Saxton, J. M. Cowley. Computer techniques for image processing in electron microscopy. Phys. Today, 32, 74(1979).

[9] J. R. Fienup. Reconstruction of an object from the modulus of its Fourier transform. Opt. Lett., 3, 27(1978).

[10] J. R. Fienup. Phase retrieval algorithms: a comparison. Appl. Opt., 21, 2758(1982).

[11] R. Hegerl, W. Hoppe. Phase evaluation in generalized diffraction (ptychography). Proceedings of the Fifth European Congress Electron Microscopy(1972).

[12] J. M. Rodenburg. Ptychography and related diffractive imaging methods. Adv. Imag. Elect. Phys., 150, 87(2008).

[13] P. D. Nellist, B. C. McCallum, J. M. Rodenburg. Resolution beyond the ‘information limit’ in transmission electron microscopy. Nature, 374, 630(1995).

[14] H. N. Chapman. Phase-retrieval X-ray microscopy by Wigner-distribution deconvolution. Ultramicroscopy, 66, 153(1996).

[15] J. M. Rodenburg, H. M. L. Faulkner. A phase retrieval algorithm for shifting illumination. Appl. Phys. Lett., 85, 4795(2004).

[16] J. M. Rodenburg, A. C. Hurst, A. G. Cullis. Transmission microscopy without lenses for objects of unlimited size. Ultramicroscopy, 107, 227(2007).

[17] P. Thibault, M. Dierolf, A. Menzel et al. High-resolution scanning X-ray diffraction microscopy. Science, 321, 379(2008).

[18] J. M. Rodenburg, A. C. Hurst, A. G. Cullis et al. Hard X-ray lensless imaging of extended objects. Phys. Rev. Lett., 98, 034801(2007).

[19] S. Cao, P. Kok, P. Li et al. Modal decomposition of a propagating matter wave via electron ptychography. Phys. Rev. A, 94, 063621(2016).

[20] L. Valzania, T. Feurer, P. Zolliker et al. Terahertz ptychography. Opt. Lett., 43, 543(2018).

[21] L. Rong, F. R. Tan, D. Y. Wang et al. High-resolution terahertz ptychography using divergent illumination and extrapolation algorithm. Opt. Laser Eng., 147, 106729(2021).

[22] A. M. Maiden, J. M. Rodenburg. An improved ptychographical phase retrieval algorithm for diffractive imaging. Ultramicroscopy, 109, 1256(2009).

[23] A. M. Maiden, M. J. Humphry, M. C. Sarahan et al. An annealing algorithm to correct positioning errors in ptychography. Ultramicroscopy, 120, 64(2012).

[24] F. C. Zhang, I. Peterson, J. Vila-Comamala et al. Translation position determination in ptychographic coherent diffraction imaging. Opt. Express, 21, 13592(2013).

[25] J. T. Dou, J. C. Wu, Y. M. Zhang et al. Accelerated convergence extended ptychographical iterative engine using multiple axial intensity constraints. Opt. Express, 28, 3587(2020).

[26] L. Loetgering, M. Q. Du, K. S. E. Eikema et al. Zpie: an autofocusing algorithm for ptychography. Opt. Lett., 45, 2030(2020).

[27] M. Pham, A. Rana, J. W. Miao et al. Semi-implicit relaxed Douglas-Rachford algorithm (sDR) for ptychography. Opt. Express., 27, 31246(2019).

[28] J. M. Cowley, A. F. Moodie. The scattering of electrons by atoms and crystals. 1. A new theoretical approach. Acta Crystallogr., 10, 609(1957).

[29] J. Kweon, S. J. Kang, Y. H. Kim et al. Impact of coronary lumen reconstruction on the estimation of endothelial shear stress: in vivo comparison of three-dimensional quantitative coronary angiography and three-dimensional fusion combining optical coherent tomography. Eur. Heart J. Card. Img., 19, 1134(2018).

[30] M. Engel, L. Kasper, B. Wilm et al. T-Hex: tilted hexagonal grids for rapid 3D imaging. Magn. Reson. Med., 85, 2507(2021).

[31] J. M. Rodenburg, A. M. Maiden, M. J. Humphry. Improvements in three dimensional imaging.

[32] A. M. Maiden, M. J. Humphry, J. M. Rodenburg. Ptychographic transmission microscopy in three dimensions using a multi-slice approach. J. Opt. Soc. Am. A, 29, 1606(2012).

[33] A. Suzuki, S. Furutaku, K. Shimomura. High-resolution multi-slice X-ray ptychography of extended thick objects. Phys. Rev. Lett., 112, 053903(2014).

[34] K. Shimomura, A. Suzuki, M. Hirose et al. Precession X-ray ptychography with multislice approach. Phys. Rev. B, 91, 214114(2015).

[35] L. Tian, L. Waller. 3D intensity and phase imaging from light field measurements in an LED array microscope. Optica, 2, 104(2015).

[36] D. Goldberger, J. Barolak, C. G. Durfee et al. Three-dimensional single-shot ptychography. Opt. Express, 28, 18887(2020).

[37] C. C. Chang, X. C. Pan, H. Tao et al. 3D single-shot ptychography with highly tilted illuminations. Opt. Express, 29, 30878(2021).

[38] X. L. He, X. C. Pan, H. Tao et al. Generalized deterministic linear model for coherent diffractive imaging. AIP. Adv., 12, 065225(2022).