[1] TORRANCE K E, SPARROW E M. Theory for off-specular reflection from roughened surfaces[J]. Journal of the Optical Society of America, 57, 1105-1114(1967).

[2] PRIEST R G, MEIER S R. Polarimetric microfacet scattering theory with applications to absorptive and reflective surfaces[J]. Optical Engineering, 41, 988-993(2002).

[3] GURTON K P, DAHMANI R. Effect of surface roughness and complex indices of refraction on polarized thermal emission[J]. Applied Optics, 44, 5361-5367(2005).

[4] HYDE IV M W, SCHMIDT J D, HAVRILLA M J. A geometrical optics polarimetric bidirectional reflectance distribution function for dielectric and metallic surfaces[J]. Optics Express, 17, 22138-22153(2009).

[5] YANG ZH Y, LU G X, ZHANG ZH W, . Analysis of infrared polarization characteristics of target in thermal radiation environment[J]. Acta Optica Sinica, 42, 0220001(2022).

[6] YANG B, YAN CH X, ZHANG J Q, et al. Refractive index and surface roughness estimation using passive multispectral and multiangular polarimetric measurements[J]. Optics Communications, 381, 336-345(2016).

[7] ZHANG Y, ZHANG Y, ZHAO H J, et al. Improved atmospheric effects elimination method for pBRDF models of painted surfaces[J]. Optics Express, 25, 16458-16475(2017).

[8] ZHANG Y, XUAN J B, ZHAO H J, et al. Roughness estimation of inhomogeneous paint based on polarization imaging detection[J]. Proceedings of SPIE, 10849, 1084910(2018).

[9] ZHAN H Y, VOELZ D G, KUPINSKI M. Parameter-based imaging from passive multispectral polarimetric measurements[J]. Optics Express, 27, 28832-28843(2019).

[10] GURTON K, FELTON M, MACK R, et al. MidIR and LWIR polarimetric sensor comparison study[J]. Proceedings of SPIE, 7672, 767205(2010).

[11] GURTON K P, FELTON M. Remote detection of buried land-mines and IEDs using LWIR polarimetric imaging[J]. Optics Express, 20, 22344-22359(2012).

[12] ROWE M P, PUGH E N, TYO J S, et al. Polarization-difference imaging: a biologically inspired technique for observation through scattering media[J]. Optics Letters, 20, 608-610(1995).

[13] SCHECHNER Y Y, KARPEL N. Recovery of underwater visibility and structure by polarization analysis[J]. IEEE Journal of Oceanic Engineering, 30, 570-587(2005).

[14] TREIBITZ T, SCHECHNER Y Y. Active polarization descattering[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 31, 385-399(2009).

[15] HAN P L, LIU F, WEI Y, et al. Optical correlation assists to enhance underwater polarization imaging performance[J]. Optics and Lasers in Engineering, 134, 106256(2020).

[16] LIU Y, YORK T, AKERS W J, et al. Complementary fluorescence-polarization microscopy using division-of-focal-plane polarization imaging sensor[J]. Journal of Biomedical Optics, 17, 116001(2012).

[17] HE CH, HE H H, CHANG J T, et al. Polarisation optics for biomedical and clinical applications: a review[J]. Light:Science & Applications, 10, 194(2021).

[18] ANDRE Y, LAHERRERE J M, BRET-DIBAT T, et al. Instrumental concept and performances of the POLDER instrument[J]. Proceedings of SPIE, 2572, 79-90(1995).

[19] CHENAULT D B, VADEN J P, MITCHELL D A, et al. Infrared polarimetric sensing of oil on water[J]. Proceedings of SPIE, 9999, 99990D(2016).

[20] YUFFA A J, GURTON K P, VIDEEN G. Three-dimensional facial recognition using passive long-wavelength infrared polarimetric imaging[J]. Applied Optics, 53, 8514-8521(2014).

[21] [21] RIGGAN B S, SHT N J, HU SH W, et al. . Estimation of visible spectrum faces from polarimetric thermal faces[C]. 2016 IEEE 8th International Conference on Biometrics They, Applications Systems (BTAS), IEEE, 2016: 17.

[22] ZHANG J H, ZHANG Y, SHI ZH G, . Reflected light separation on transparent object surface based on normal vector estimation[J]. Acta Optica Sinica, 41, 1526001(2021).

[23] LI N, ZHAO Y Q, PAN Q, et al. Removal of reflections in LWIR image with polarization characteristics[J]. Optics Express, 26, 16488-16504(2018).

[24] KONG N, TAI Y W, SHIN J S. A physically-based approach to reflection separation: from physical modeling to constrained optimization[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 36, 209-221(2014).

[25] NARASIMHAN S G, NAYAR S K. Vision and the atmosphere[J]. International Journal of Computer Vision, 48, 233-254(2002).

[26] SCHECHNER Y Y, NARASIMHAN S G, NAYAR S K. Polarization-based vision through haze[J]. Applied Optics, 42, 511-525(2003).

[27] LI N, ZHAO Y Q, PAN Q, et al. Illumination-invariant road detection and tracking using LWIR polarization characteristics[J]. ISPRS Journal of Photogrammetry and Remote Sensing, 180, 357-369(2021).

[28] LI N, ZHAO Y Q, WU R Y, et al. Polarization-guided road detection network for LWIR division-of-focal-plane camera[J]. Optics Letters, 46, 5679-5682(2021).

[29] YAROSLAVSKY A N, FENG X, YU S H, et al. Dual-wavelength optical polarization imaging for detecting skin cancer margins[J]. Journal of Investigative Dermatology, 140, 1994-2000.e1(2020).

[30] MAIGNAN F, BRÉON F M, FÉDÈLE E, et al. Polarized reflectances of natural surfaces: spaceborne measurements and analytical modeling[J]. Remote Sensing of Environment, 113, 2642-2650(2009).

[31] RIZKI AKBAR P, TETUKO S S J, KUZE H. A novel circularly polarized synthetic aperture radar (CP-SAR) system onboard a spaceborne platform[J]. International Journal of Remote Sensing, 31, 1053-1060(2010).

[32] CHUN C S L, FLEMING D L, HARVEY W A, et al. Polarization-sensitive thermal imaging sensor[J]. Proceedings of SPIE, 2552, 438-444(1995).

[33] PEZZANITI J L, CHENAULT D, GURTON K, et al. Detection of obscured targets with IR polarimetric imaging[J]. Proceedings of SPIE, 9072, 90721D(2014).

[34] TYO J S, GOLDSTEIN D L, CHENAULT D B, et al. Review of passive imaging polarimetry for remote sensing applications[J]. Applied Optics, 45, 5453-5469(2006).

[35] ZHOU K, SHAN ZH, ZHANG Q, . Research progresses of MEMS Fabry-Perot filtering chips and their applications for spectral detection[J]. Acta Optica Sinica, 42, 0800001(2022).

[36] [36] GARLICK G F J, STEIGMANN G A, LAMB W E. Differential optical polarization detects: US, 3992571[P]. 19761116.

[37] FARLOW C A, CHENAULT D B, PEZZANITI J L, et al. Imaging polarimeter development and applications[J]. Proceedings of SPIE, 4481, 118-125(2002).

[38] DIRIX Y, TERVOORT T A, BASTIAANSEN C. Optical properties of oriented polymer/dye polarizers[J]. Macromolecules, 28, 486-491(1995).

[39] WOLFF L B, MANCINI T A, POULIQUEN P, et al. Liquid crystal polarization camera[J]. IEEE Transactions on Robotics and Automation, 13, 195-203(1997).

[40] [40] BROER D J, VAN DER V J. Method of manufacturing a polarization filter a polarization filter so obtained: US, 5024850[P]. 19910618.

[41] ZHAO X J, BERMAK A, BOUSSAID F, et al. Liquid-crystal micropolarimeter array for full Stokes polarization imaging in visible spectrum[J]. Optics Express, 18, 17776-17787(2010).

[42] MYHRE G, HSU W L, PEINADO A, et al. Liquid crystal polymer full-stokes division of focal plane polarimeter[J]. Optics Express, 20, 27393-27409(2012).

[43] ZHANG SH Y, SUN Z J, MU Q Q, . Review on liquid crystal micropolarizer array for polarization imaging[J]. Chinese Journal of Liquid Crystals and Displays, 37, 292-309(2022).

[44] WANG X Q, SHEN D, ZHENG ZH G, . Review on liquid crystal photoalignment technologies[J]. Chinese Journal of Liquid Crystals and Displays, 30, 737-751(2015).

[45] ZHAO J C, QIU M, YU X CH, et al. Defining deep-subwavelength-resolution, wide-color-gamut, and large-viewing-angle flexible subtractive colors with an ultrathin asymmetric Fabry-Perot lossy cavity[J]. Advanced Optical Materials, 7, 1900646(2019).

[46] BOKOR N, SHECHTER R, DAVIDSON N, et al. Achromatic phase retarder by slanted illumination of a dielectric grating with period comparable with the wavelength[J]. Applied Optics, 40, 2076-2080(2001).

[47] FU X H, LIN X M, ZHANG G, . Development of infrared wide band polarizing elements with subwavelength metal wire grids[J]. Chinese Journal of Lasers, 48, 0903002(2021).

[48] YEH P. A new optical model for wire grid polarizers[J]. Optics Communications, 26, 289-292(1978).

[49] LALANNE P, LEMERCIER-LALANNE D. On the effective medium theory of subwavelength periodic structures[J]. Journal of Modern Optics, 43, 2063-2085(1996).

[50] TYAN R C, SALVEKAR A A, CHOU H P, et al. Design, fabrication, and characterization of form-birefringent multilayer polarizing beam splitter[J]. Journal of the Optical Society of America A, 14, 1627-1636(1997).

[51] AHN S W, LEE K D, KIM J S, et al. Fabrication of a 50 nm half-pitch wire grid polarizer using nanoimprint lithography[J]. Nanotechnology, 16, 1874-1877(2005).

[52] YAMADA I, NISHII J, SAITO M. Incident angle and temperature dependence of WSi wire-grid polarizer[J]. Infrared Physics & Technology, 63, 92-96(2014).

[53] XIA J, YUAN ZH H, WANG CH, et al. Design and fabrication of a linear polarizer in the 8-12μm infrared region with multilayer nanogratings[J]. OSA Continuum, 2, 1683-1692(2019).

[54] ZHANG ZH G, DONG F L, CHENG T, et al. Nano-fabricated pixelated micropolarizer array for visible imaging polarimetry[J]. Review of Scientific Instruments, 85, 105002(2014).

[55] SUN D, FENG B, YANG B, et al. Design and fabrication of an InGaAs focal plane array integrated with linear-array polarization grating[J]. Optics Letters, 45, 1559-1562(2020).

[56] GRUEV V, PERKINS R, YORK T. CCD polarization imaging sensor with aluminum nanowire optical filters[J]. Optics Express, 18, 19087-19094(2010).

[57] GRUEV V. Fabrication of a dual-layer aluminum nanowires polarization filter array[J]. Optics Express, 19, 24361-24369(2011).

[58] MA X, DONG F L, ZHANG ZH G, et al. Pixelated-polarization-camera-based polarimetry system for wide real-time optical rotation measurement[J]. Sensors and Actuators B:Chemical, 283, 857-864(2019).

[59] CAO T, LIU K, LI Y, . Tunable optical metamaterials and their applications[J]. Chinese Optics, 14, 968-985(2021).

[60] SHELBY R A, SMITH D R, SCHULTZ S. Experimental verification of a negative index of refraction[J]. Science, 292, 77-79(2001).

[61] VESELAGO V G. The electrodynamics of substances with simultaneously negative values of ε and μ[J]. Soviet Physics Uspekhi, 10, 509-514(1968).

[62] TIAN X Y, YIN L X, LI D CH. Current situation and trend of fabrication technologies for three-dimensional metamaterials[J]. Opto-Electronic Engineering, 44, 69-76(2017).

[63] YU X CH, XU Y Q, CAI J CH, . Progress of tunable micro-nano filtering structures[J]. Chinese Optics, 14, 1069-1088(2021).

[64] FU R, LI Z L, ZHENG G X. Research development of amplitude-modulated metasurfaces and their functional devices[J]. Chinese Optics, 14, 886-899(2021).

[65] YU N F, GENEVET P, KATS M A, et al. Light propagation with phase discontinuities: generalized laws of reflection and refraction[J]. Science, 334, 333-337(2011).

[66] YU N F, AIETA F, GENEVET P, et al. A broadband, background-free quarter-wave plate based on plasmonic metasurfaces[J]. Nano Letters, 12, 6328-6333(2012).

[67] DENG Y D, CAI Z R, DING Y T, et al. Recent progress in metasurface-enabled optical waveplates[J]. Nanophotonics, 11, 2219-2244(2022).

[68] JIANG ZH H, LIN L, MA D, et al. Broadband and wide field-of-view plasmonic metasurface-enabled waveplates[J]. Scientific Reports, 4, 7511(2014).

[69] LIU D M, LV T T, LIU Q, . Performance study on switchable and multifunctional metasurface wave plate[J]. Chinese Optics, 14, 1029-1037(2021).

[70] LI J X, WANG Y Q, CHEN CH, et al. From lingering to rift: metasurface decoupling for near- and far-field functionalization[J]. Advanced Materials, 33, 2007507(2021).

[71] WU T, ZHANG X Q, XU Q, et al. Dielectric metasurfaces for complete control of phase, amplitude, and polarization[J]. Advanced Optical Materials, 10, 2101223(2022).

[72] KARIMI E, SCHULZ S A, DE LEON I, et al. Generating optical orbital angular momentum at visible wavelengths using a plasmonic metasurface[J]. Light:Science & Applications, 3, e167(2014).

[73] AHMED H, KIM H, ZHANG Y B, et al. Optical metasurfaces for generating and manipulating optical vortex beams[J]. Nanophotonics, 11, 941-956(2022).

[74] YU Y, ZHONG F, JIANG X, . Dynamical optical beam produced in rotational metasurface based on coherent spin hall effect[J]. Chinese Optics, 14, 927-934(2021).

[75] NI Y B, WEN SH, SHEN Z CH, . Multidimensional light field sensing based on metasurfaces[J]. Chinese Journal of Lasers, 48, 1918003(2021).

[76] KILDISHEV A V, BOLTASSEVA A, SHALAEV V M. Planar photonics with metasurfaces[J]. Science, 339, 1232009(2013).

[77] [77] MAIER S A. Plasmonics: Fundamentals Applications[M]. ZHANG T, WANG Q L, ZHANG X Y, et al. , trans. Nanjing: Southeast University Press, 2014: 313. (in Chinese)

[78] AIETA F, GENEVET P, KATS M A, et al. Aberration-free ultrathin flat lenses and axicons at telecom wavelengths based on plasmonic metasurfaces[J]. Nano Letters, 12, 4932-4936(2012).

[79] NI X J, ISHII S, KILDISHEV A V, et al. Ultra-thin, planar, Babinet-inverted plasmonic metalenses[J]. Light:Science & Applications, 2, e72(2013).

[80] SUN SH L, YANG K Y, WANG C M, et al. High-efficiency broadband anomalous reflection by gradient meta-surfaces[J]. Nano Letters, 12, 6223-6229(2012).

[81] DING F, YANG Y Q, DESHPANDE R A, et al. A review of gap-surface plasmon metasurfaces: fundamentals and applications[J]. Nanophotonics, 7, 1129-1156(2018).

[82] KIM H C, CHENG X. SERS-active substrate based on gap surface plasmon polaritons[J]. Optics Express, 17, 17234-17241(2009).

[83] GUO Q Q, CHEN Y H. Enhanced nonlinear optical effects based on strong coupling between epsilon-near-zero mode and gap surface plasmons[J]. Acta Physica Sinica, 70, 187303(2021).

[84] PORS A, NIELSEN M G, BOZHEVOLNYI S I. Plasmonic metagratings for simultaneous determination of Stokes parameters[J]. Optica, 2, 716-723(2015).

[85] SHALTOUT A, LIU J J, KILDISHEV A, et al. Photonic spin hall effect in gap–plasmon metasurfaces for on-chip chiroptical spectroscopy[J]. Optica, 2, 860-863(2015).

[86] BOROVIKS S, DESHPANDE R A, MORTENSEN N A, et al. Multifunctional metamirror: polarization splitting and focusing[J]. ACS Photonics, 5, 1648-1653(2018).

[87] DING F, CHEN Y T, BOZHEVOLNYI S I. Gap-surface plasmon metasurfaces for linear-polarization conversion, focusing, and beam splitting[J]. Photonics Research, 8, 707-714(2020).

[88] ZHANG J, ELKABBASHIM, WEIR, et al. Plasmon metasurfaces with 42.39% transmission efficiency in visible[J]. Light: Science & Applications, 8, 53(2019).

[89] WEI SH W, YANG ZH Y, ZHAO M. Design of ultracompact polarimeters based on dielectric metasurfaces[J]. Optics Letters, 42, 1580-1583(2017).

[90] LIN D M, FAN P Y, HASMAN E, et al. Dielectric gradient metasurface optical elements[J]. Science, 345, 298-302(2014).

[91] HU Y Q, WANG X D, LUO X H, et al. All-dielectric metasurfaces for polarization manipulation: principles and emerging applications[J]. Nanophotonics, 9, 3755-3780(2020).

[92] KHORASANINEJAD M, CHEN W T, ZHU A Y, et al. Multispectral chiral imaging with a metalens[J]. Nano Letters, 16, 4595-4600(2016).

[93] YANG ZH Y, WANG ZH K, WANG Y X, et al. Generalized Hartmann-Shack array of dielectric metalens sub-arrays for polarimetric beam profiling[J]. Nature Communications, 9, 4607(2018).

[94] LIU Y J, ZHANG F, XIE T, . Polarization-multiplexed metalens enabled by adjoint optimization[J]. Chinese Optics, 14, 754-763(2021).

[95] KHORASANINEJAD M, CHEN W T, DEVLIN R C, et al. Metalenses at visible wavelengths: Diffraction-limited focusing and subwavelength resolution imaging[J]. Science, 352, 1190-1194(2016).

[96] ZHAO J C, YU X CH, ZHOU K, et al. Polarization-sensitive subtractive structural color used for information encoding and dynamic display[J]. Optics and Lasers in Engineering, 138, 106421(2021).

[97] FAN ZH B, CHEN Z M, ZHOU X, . Recent advances in silicon nitride-based photonic devices and applications[J]. Chinese Optics, 14, 998-1018(2021).

[98] PANCHARATNAM S. Generalized theory of interference and its applications[J]. Proceedings of the Indian Academy of Sciences - Section A, 44, 398-417(1956).

[99] BERRY M V. Quantal phase factors accompanying adiabatic changes[J]. Proceedings of the Royal Society A:Mathematical, Physical and Engineering Sciences, 392, 45-57(1984).

[100] HSIAO H H, CHU C H, TSAI D P. Fundamentals and applications of metasurfaces[J]. Small Methods, 1, 1600064(2017).

[101] ARBABI A, HORIE Y, BAGHERI M, et al. Dielectric metasurfaces for complete control of phase and polarization with subwavelength spatial resolution and high transmission[J]. Nature Nanotechnology, 10, 937-943(2015).

[102] ARBABI E, KAMALI S M, ARBABI A, et al. Full-Stokes imaging polarimetry using dielectric metasurfaces[J]. ACS Photonics, 5, 3132-3140(2018).

[103] YAN CH, LI X, PU M B, et al. Midinfrared real-time polarization imaging with all-dielectric metasurfaces[J]. Applied Physics Letters, 114, 161904(2019).

[104] REN Y Z, GUO SH H, ZHU W Q, et al. Full-Stokes polarimetry for visible light enabled by an all-dielectric metasurface[J]. Advanced Photonics Research, 3, 2100373(2022).

[105] RUBIN N A, D’AVERSA G, CHEVALIER P, et al. Matrix Fourier optics enables a compact full-Stokes polarization camera[J]. Science, 365, eaax1839(2019).

[106] RUBIN N A, CHEVALIER P, JUHL M, et al. Imaging polarimetry through metasurface polarization gratings[J]. Optics Express, 30, 9389-9412(2022).

[107] CHEN W T, ZHU A Y, SANJEEV V, et al. A broadband achromatic metalens for focusing and imaging in the visible[J]. Nature Nanotechnology, 13, 220-226(2018).

[108] [108] LI X X. Broadb achromatic polarization imaging based on metasurface[D]. Harbin: Harbin Institute of Technology, 2021: 710. (in Chinese)

[109] KHORASANINEJAD M, SHI Z, ZHU A Y, et al. Achromatic metalens over 60 nm bandwidth in the visible and metalens with reverse chromatic dispersion[J]. Nano Letters, 17, 1819-1824(2017).

[110] AIETA F, KATS M A, GENEVET P, et al. Multiwavelength achromatic metasurfaces by dispersive phase compensation[J]. Science, 347, 1342-1345(2015).

[111] WANG SH M, WU P C, SU V C, et al. Broadband achromatic optical metasurface devices[J]. Nature Communications, 8, 187(2017).

[112] CHENG Q Q, MA M L, YU D, et al. Broadband achromatic metalens in terahertz regime[J]. Science Bulletin, 64, 1525-1531(2019).

[113] OU K, YU F L, LI G H, et al. Mid-infrared polarization-controlled broadband achromatic metadevice[J]. Science Advances, 6, eabc0711(2020).

[114] [114] OU K. Manipulation the light based on artificial microstructure metasurfaces its applications[D]. Shanghai: University of Chinese Academy of Sciences (Shanghai Institute of Technical Physics, Chinese Academy of Sciences), 2021: 4760. (in Chinese)

[115] FENG X, WANG Y X, WEI Y X, et al. Optical multiparameter detection system based on a broadband achromatic metalens array[J]. Advanced Optical Materials, 9, 2100772(2021).

[116] XIAO X J, ZHU SH N, LI T. Design and parametric analysis of the broadband achromatic flat lens[J]. Infrared and Laser Engineering, 49, 20201032(2020).

[117] CHEN J, HU SH SH, ZHU SH N, et al. Metamaterials: from fundamental physics to intelligent design[J]. Interdisciplinary Materials, 3, 5-29(2023).

[118] WIECHA P R, ARBOUET A, GIRARD C, et al. Deep learning in nano-photonics: inverse design and beyond[J]. Photonics Research, 9, B182-B200(2021).

[119] WANG P, MOHAMMAD N, MENON R. Chromatic-aberration-corrected diffractive lenses for ultra-broadband focusing[J]. Scientific Reports, 6, 21545(2016).

[120] SHENG X H, ZHOU SH D, XI K L, . Multi-order refractive index thin-film flat lens based on phase change materials[J]. Acta Optica Sinica, 42, 1916002(2022).

[121] MEEM M, BANERJI S, MAJUMDER A, et al. Broadband lightweight flat lenses for long-wave infrared imaging[J]. Proceedings of the National Academy of Sciences of the United States of America, 116, 21375-21378(2019).

[122] BANERJI S, MEEM M, MAJUMDER A, et al. Imaging with flat optics: metalenses or diffractive lenses?[J]. Optica, 6, 805-810(2019).

[123] WANG F L, GENG G ZH, WANG X Q, et al. Visible achromatic metalens design based on artificial neural network[J]. Advanced Optical Materials, 10, 2101842(2022).

[124] GU Y J, HAO R, LI E P. Independent bifocal metalens design based on deep learning algebra[J]. IEEE Photonics Technology Letters, 33, 403-406(2021).

[125] [125] XU D. Design of phasemodulating metasurface device based on deep learning[D]. Chengdu: University of Chinese Academy of Sciences (The Institute of Optics Electronics, the Chinese Academy of Sciences), 2021: 59. (in Chinese)

[126] MA W, XU Y H, XIONG B, et al. Pushing the limits of functionality-multiplexing capability in metasurface design based on statistical machine learning[J]. Advanced Material, 34, 2110022(2022).

[127] AN X P, CAO Y, WEI Y X, et al. Broadband achromatic metalens design based on deep neural networks[J]. Optics Letters, 46, 3881-3884(2021).

[128] ZHU R CH, QIU T SH, WANG J F, et al. Phase-to-pattern inverse design paradigm for fast realization of functional metasurfaces via transfer learning[J]. Nature Communications, 12, 2974(2021).

[129] LIPTON Z C. The mythos of model interpretability: In machine learning, the concept of interpretability is both important and slippery[J]. Queue, 16, 31-57(2018).

[130] SHE A L, ZHANG SH Y, SHIAN S, et al. Adaptive metalenses with simultaneous electrical control of focal length, astigmatism, and shift[J]. Science Advances, 4, eaap9957(2018).

[131] SHAPIRA C, YARIV I, ANKRI R, et al. Effect of optical magnification on the detection of the reduced scattering coefficient in the blue regime: theory and experiments[J]. Optics Express, 29, 22228-22239(2021).

[132] LIM T Y, PARK S C. Achromatic and athermal lens design by redistributing the element powers on an athermal glass map[J]. Optics Express, 24, 18049-18058(2016).

[133] XIE N, CUI Q F. Athermalization design of visible light optical system based on grouping by weight[J]. Acta Optica Sinica, 38, 1222001(2018).

[134] ASHTON A. Zoom lens systems[J]. Proceedings of SPIE, 163, 92-98(1979).

[135] PARR-BURMAN P, GARDAM A. The development of a compact I. R. zoom telescope[J]. Proceedings of SPIE, 590, 11-17(1986).

[136] EE H S, AGARWAL R. Tunable metasurface and flat optical zoom lens on a stretchable substrate[J]. Nano Letters, 16, 2818-2823(2016).

[137] SONG SH CH, MA X L, PU M B, et al. Actively tunable structural color rendering with tensile substrate[J]. Advanced Optical Materials, 5, 1600829(2017).

[138] ARBABI E, ARBABI A, KAMALI S M, et al. MEMS-tunable dielectric metasurface lens[J]. Nature Communications, 9, 812(2018).

[139] CUI T, BAI B F, SUN H B. Tunable metasurfaces based on active materials[J]. Advanced Functional Materials, 29, 1806692(2019).

[140] KIM J, SEONG J, YANG Y, et al. Tunable metasurfaces towards versatile metalenses and metaholograms: a review[J]. Advanced Photonics, 4, 024001(2022).

[141] LININGER A, ZHU A Y, PARK J S, et al. Optical properties of metasurfaces infiltrated with liquid crystals[J]. Proceedings of the National Academy of Sciences of the United States of America, 117, 20390-20396(2020).

[142] XU N, HAO Y, JIE K Q, et al. Electrically-driven zoom metalens based on dynamically controlling the phase of barium titanate (BTO) column antennas[J]. Nanomaterials, 11, 729(2021).

[143] QIN SH, XU N, HUANG H, et al. Near-infrared thermally modulated varifocal metalens based on the phase change material Sb₂S₃[J]. Optics Express, 29, 7925-7934(2021).

[144] YIN X H, STEINLE T, HUANG L L, et al. Beam switching and bifocal zoom lensing using active plasmonic metasurfaces[J]. Light:Science & Applications, 6, e17016(2017).

[145] YU ZH N, DESHPANDE P, WU W, et al. Reflective polarizer based on a stacked double-layer subwavelength metal grating structure fabricated using nanoimprint lithography[J]. Applied Physics Letters, 77, 927-929(2000).

[146] KANG W D, CHU J K, ZENG X W, et al. Large-area flexible infrared nanowire grid polarizer fabricated using nanoimprint lithography[J]. Applied Optics, 57, 5230-5234(2018).

[147] YAMADA I, FUKUMI K, NISHII J, et al. Infrared wire-grid polarizer with Y₂O₃ ceramic substrate[J]. Optics Letters, 35, 3111-3113(2010).

[148] LI A L, DUAN H G, JIA H H, . Research progress of metalenses in mid-infrared band[J]. Optics and Precision Engineering, 30, 2313-2331(2022).

[149] PEZZANITI J L, CHENAULT D B. A division of aperture MWIR imaging polarimeter[J]. Proceedings of SPIE, 5888, 239-250(2005).

[150] HAO J, WANG Y, ZHOU K, et al. New diagonal micropolarizer arrays designed by an improved model in Fourier domain[J]. Scientific Reports, 11, 5778(2021).

[151] HAO J, WANG Y, ZHOU K, . Optimized design model of novel diagonal micropolarizer arrays[J]. Optics and Precision Engineering, 29, 2363-2374(2021).

[152] YU X CH, ZHAO J C, YU Y T. Research progress of pixel-level integrated devices for spectral imaging[J]. Optics and Precision Engineering, 27, 999-1012(2019).

[153] YU X CH, SU Y, SONG X K, et al. Batch fabrication and compact integration of customized multispectral filter arrays towards snapshot imaging[J]. Optics Express, 29, 30655-30665(2021).

[154] GAN ZH F, FENG H T, CHEN L Y, et al. Spatial modulation of nanopattern dimensions by combining interference lithography and grayscale-patterned secondary exposure[J]. Light:Science & Applications, 11, 89(2022).

[155] [155] HOU M M, CHEN Y, YI F. Lightweight longwave infrared camera via a single 5centimeteraperture metalens[C]. 2022 Conference on Lasers ElectroOptics (CLEO), IEEE, 2022: 12.