[1] S. W. Seo, S. Han, J. H. Seo, Y. M. Kim, M. S. Kang, N. K. Min, W. B. Choi, M. Y. Sung. Microelectromechanical-system-based variable-focus liquid lens for capsule endoscopes. Jpn. J. Appl. Phys., 48, 052404(2009).
[2] H.-S. Ee, R. Agarwal. Tunable metasurface and flat optical zoom lens on a stretchable substrate. Nano Lett., 16, 2818-2823(2016).
[3] S. M. Kamali, E. Arbabi, A. Arbabi, Y. Horie, A. Faraon. Highly tunable elastic dielectric metasurface lenses. Laser Photon. Rev., 10, 1002-1008(2016).
[4] E. Arbabi, A. Arbabi, S. M. Kamali, Y. Horie, M. Faraji-Dana, A. Faraon. MEMS-tunable dielectric metasurface lens. Nat. Commun., 9, 812(2018).
[5] Z. Han, S. Colburn, A. Majumdar, K. F. Böhringer. MEMS-actuated metasurface Alvarez lens. Microsyst. Nanoeng., 6, 79(2020).
[6] Z. Han, S. Colburn, A. Majumdar, K. F. Bohringer. Millimeter-scale focal length tuning with MEMS-integrated meta-optics employing high-throughput fabrication(2021).
[7] E. R. Dowski, W. T. Cathey. Extended depth of field through wave-front coding. Appl. Opt., 34, 1859-1866(1995).
[8] Z. Zalevsky. Extended depth of focus imaging: a review. SPIE Rev., 1, 018001(2010).
[9] R. K. Maia. Extended depth of focus IOLs: the next chapter in refractive technology?. J. Refract. Surg., 33, 146-149(2017).
[10] S. Banerji, M. Meem, A. Majumder, B. Sensale-Rodriguez, R. Menon. Extreme-depth-of-focus imaging with a flat lens. Optica, 7, 214-217(2020).
[11] S. M. Kamali, E. Arbabi, A. Arbabi, A. Faraon. A review of dielectric optical metasurfaces for wavefront control. Nanophotonics, 7, 1041-1068(2018).
[12] A. Zhan, S. Colburn, R. Trivedi, T. K. Fryett, C. M. Dodson, A. Majumdar. Low-contrast dielectric metasurface optics. ACS Photon., 3, 209-214(2016).
[13] S. Colburn, A. Zhan, A. Majumdar. Metasurface optics for full-color computational imaging. Sci. Adv., 4, eaar2114(2018).
[14] L. Huang, J. Whitehead, S. Colburn, A. Majumdar. Design and analysis of extended depth of focus metalenses for achromatic computational imaging. Photon. Res., 8, 1613-1623(2020).
[15] E. Bayati, R. Pestourie, S. Colburn, Z. Lin, S. G. Johnson, A. Majumdar. Inverse designed metalenses with extended depth of focus. ACS Photon., 7, 873-878(2020).
[17] W. T. Cathey, E. R. Dowski. New paradigm for imaging systems. Appl. Opt., 41, 6080-6092(2002).
[18] R. Pestourie, C. Pérez-Arancibia, Z. Lin, W. Shin, F. Capasso, S. G. Johnson. Inverse design of large-area metasurfaces. Opt. Express, 26, 33732-33747(2018).
[19] E. Tseng, S. Colburn, J. Whitehead, L. Huang, S.-H. Baek, A. Majumdar, F. Heide. Neural nano-optics for high-quality thin lens imaging. Nat. Commun., 12, 6493(2021).
[20] U. Akpinar, E. Sahin, M. Meem, R. Menon, A. Gotchev. Learning wavefront coding for extended depth of field imaging(2020).
[21] P. Getreuer. Total variation deconvolution using split Bregman. Image Process. Line, 2, 158-174(2012).
[22] B. Xu, H. Li, S. Gao, X. Hua, C. Yang, C. Chen, F. Yan, S. N. Zhu, T. Li. Metalens-integrated compact imaging devices for wide-field microscopy. Adv. Photon., 2, 026003(2020).
[23] S. R. M. Rostami, S. Pinilla, I. Shevkunov, V. Katkovnik, K. Egiazarian. Power-balanced hybrid optics boosted design for achromatic extended depth-of-field imaging via optimized mixed OTF. Appl. Opt., 60, 9365-9378(2021).
[24] . Liquid lenses in machine vision(2019).
[25] B. Forster, D. Van De Ville, J. Berent, D. Sage, M. Unser. Complex wavelets for extended depth-of-field: a new method for the fusion of multichannel microscopy images. Microsc. Res. Tech., 65, 33-42(2004).
[26] F. Aguet, D. Van De Ville, M. Unser. Model-based 2.5-D deconvolution for extended depth of field in brightfield microscopy. IEEE Trans. Image Process., 17, 1144-1153(2008).