[1] [1] ROGER J-C，SANTER R，HERMAN M，et al. Polarization of the solar light scattered by the earth-atmosphere system as observed from the U. S. shuttle[J]. Remote Sens Environ，1994（48）：275-90.

[2] [2] WOLFF L，MANCINI T，POULIQUEN P，et al. Liquid crystal polarization camera[J]. Robotics and Automation，IEEE Transactions on，1997（13）：195-203.

[4] [4] PEZZANITI J，CHENAULT D，ROCHE M，et al. Wave slope measurement using imaging polarimetry[J]. Proc of SPIE，2009（7317）：73170B1-13.

[10] [10] PEZZANITI J，CHENAULT D, ROCHE M，et al. Wave slope measurement using imaging polarimetry[J]. Proceeding of SPIE, 2009（7317）：73170B1-13.

[11] [11] MUDGE J，VIRGEN M. Near-infrared simultaneous Stokes imaging polarimeter: integration, field acquisitions，and instrument error estimation[J]. Proceeding of SPIE，2011（8160）：81600B1-14.

[12] [12] GEYER E H，JOCKERS K，KISELEV N N，et al. A novel quadruple beam imaging polarimeter and its application to comet Tanaka-Machholz 1992 X[J]. Astrophys Space Sci，1996，239（2）：259-74.

[13] [13] OLIVA E. Wedged double Wollaston，a device for single shot polarimetric measurements[J]. Astron Astrophys Suppl Ser，1997，123（3）：589-92.

[14] [14] PERNECHELE C，GIRO E，FANTINEL D. Device for optical linear polarization measurements with a single exposure[M]. SPIE，2003.

[15] [15] KAWABATA K，UEHARA T，YAMANAKA M，et al. Rapidly-responding optical polarimetry of GRB afterglows with hiroshima 1.5 m telescope and one-shot wide-field polarimeter[J]. 2010（1279）：355-6.

[16] [16] KAWABATA K，NAGAE O，CHIYONOBU S，et al. Wide-field one-shot optical polarimeter： HOWPol[M]. SPIE，2008.

[17] [17] MUDGE J，VIRGEN M. Near-infrared simultaneous Stokes imaging polarimeter： integration，field acquisitions，and instrument error estimation[J]. Proc of SPIE，2011，8160（20）：25-31.

[18] [18] NORDIN G P，MEIER J T，DEGUZMAN P C，et al. Micropolarizer array for infrared imaging polarimetry[J]. J Opt Soc Am A，1999，16（5）：1168-74.

[19] [19] ZHAO X，BOUSSAID F，BERMAK A，et al. High-resolution thin “guest-host” micropolarizer arrays for visible imaging polarimetry[J]. Opt Express，2011，19（6）： 5565-73.

[20] [20] GOUDAIL F，LI X，BOFFETY M，et al. Precision of retardance autocalibration in full-Stokes division-of-focal-plane imaging polarimeters[J]. Opt Lett，2019，44（22）：5410-3.

[21] [21] PELTZER J J，FLAMMER P D，FURTAK T E，et al. Ultra-high extinction ratio micropolarizers using plasmonic lenses[J]. Opt Express，2011，19（19）： 18072-9.

[22] [22] HSU W-L，BALAKRISHNAN K，IBN-ELHAJ M，et al. Infrared liquid crystal polymer micropolarizer[J]. Appl Opt，2014，53（23）：5252-8.

[23] [23] ZHAO X，BERMAK A，BOUSSAID F，et al. High-resolution photoaligned liquid-crystal micropolarizer array for polarization imaging in visible spectrum [J]. Opt Lett，2009，34（23）：3619-21.

[24] [24] LI W，COPPENS Z J，BESTEIRO L V，et al. Circularly polarized light detection with hot electrons in chiral plasmonic metamaterials[J]. Nat Commun，2015，6（1）： 8379.

[25] [25] CAO W，YANG X，GAO J. Broadband polarization conversion with anisotropic plasmonic metasurfaces[J]. Sci Rep，2017，7（1）： 8841.

[26] [26] ZHANG Z，DONG F，CHENG T，et al. Nano-fabricated pixelated micropolarizer array for visible imaging polarimetry[J]. The Review of Scientific Instruments，2014（85）：105002.

[28] [28] CAI J，YU M，FAN Y，et al. Fabrication of micropolarizer array for visible polarization imaging[C]//Proceedings of the 2015 International Conference on Manipulation，Manufacturing and Measurement on the Nanoscale （3M-NANO），2015：103-106.

[29] [29] BROCK N, KIMBROUGH B，MILLERD J. A pixelated polarizer-based camera for instantaneous interferometric measurements[J]. Proceeding of SPIE，2011（8160）： 81600W1-9.

[30] [30] JING，BAI，CHU，et al. Chip-integrated plasmonic flat optics for mid-infrared full-Stokes polarization detection[J]. Photonics Research，2019，7（9）：116-125.

[31] [31] STARK J A. Adaptive image contrast enhancement using generalizations of histogram equalization[J]. IEEE T Image Process，2000，9（5）：889-96.

[32] [32] YEONG-TAEG K. Contrast enhancement using brightness preserving bi-histogram equalization [J]. IEEE T Consum Electr，1997，43（1）：1-8.

[33] [33] ABDULLAH-AL-WADUD M，KABIR M H，DEWAN M A A，et al. A dynamic histogram equalization for image contrast enhancement[J]. IEEE T Consum Electr，2007，53（2）：593-600.

[34] [34] WANG X，CHEN L. Contrast enhancement using feature-preserving bi-histogram equalization[J]. Signal，Image and Video Processing，2018，12（4）：685-92.

[35] [35] STARCK J，MURTAGH F，CANDES E J，et al. Gray and color image contrast enhancement by the curvelet transform[J]. IEEE T Image Process，2003，12（6）： 706-17.

[36] [36] HEMALATHA J，DEVI M K K，GEETHA S. Improving image steganalyser performance through curvelet transform denoising[J]. Cluster Computing，2019，22（5）： 11821-39.

[37] [37] CAO G，TIAN H，YU L，et al. Fast contrast enhancement by adaptive pixel value stretching[J]. Int J Distrib Sens Netw，2018，14（8）：1550147718793803.

[38] [38] JINSHAN T，PELI E，ACTON S. Image enhancement using a contrast measure in the compressed domain[J]. IEEE Signal Proc Let，2003，10（10）：289-92.

[39] [39] BROWN A J. Spectral curve fitting for automatic hyperspectral data analysis[J]. IEEE T Geosci Remote，2006，44（6）：1601-8.

[41] [41] CREMER F，JONG W D，SCHUTTE K. Infrared polarization measurements and modelling applied to surface laid anti-personnel landmines[J]. Opt Eng，2002，41（5）：1021-32，12.

[42] [42] TERRIER P，DEVLAMINCK V，CHARBOIS J. Segmentation of rough surfaces using a polarization imaging system[J]. Journal of the Optical Society of America A，Optics，Image Science，and Vision，2008（25）：423-30.

[43] [43] ANNA G，GOUDAIL F，DOLFI D. Optimal discrimination of multiple regions with an active polarimetric imager[J]. Opt Express，2011，19（25）：25367-78.

[44] [44] SHORT N J，YUFFA A J，VIDEEN G，et al. Effects of surface materials on polarimetric-thermal measurements： applications to face recognition[J]. Appl Opt，2016，55（19）：5226-33.

[45] [45] PARNET F，FADE J，ORTEGA-QUIJANO N，et al. Active infrared polarimetric imaging demonstrator by orthogonality breaking sensing[M]. SPIE，2017.

[46] [46] DU W，JIA W，ZHANG Z，et al. Optimization of the infrared Stokes imaging polarimeter[M]. SPIE，2017.

[53] [53] CHEN Z，WANG X，ZHANG M，et al. Study of atmospheric effects on infrared polarization imaging system based on polarized Monte Carlo method[M]. SPIE，2012.

[58] [58] DU W，JIA W，ZHANG Z，et al. Optimization of the infrared Stokes imaging polarimeter[M]. SPIE，2017.

[59] [59] WHITEHEAD V S. Summary of observations performed and the preliminary findings in the space shuttle polarization experiment[M]. SPIE，1992.

[60] [60] ISRAEL S，DUGGIN M J. Characterization of terrestrial features using space-shuttle-based polarimetry[M]. SPIE，1992.

[61] [61] ROGER J C，SANTER R P，HERMAN M，et al. Potentialities in remote sensing of the polarization of the reflected solar light as illustrated from the U. S. space shuttle measurements[M]. SPIE，1992.

[62] [62] SIDRAN M，EGAN W. Analysis of sea-surface polarization imagery of Hawaii environs obtained by the space shuttle[M]. SPIE，1992.

[63] [63] DESCHAMPS P，BREON F，LEROY M，et al. The POLDER mission： instrument characteristics and scientific objectives [J]. IEEE T Geosci Remote，1994，32（3）：598-615.

[64] [64] GOLOUB P，HERMAN M，PAROL F. Polarization of clouds[M]. SPIE，1995.

[65] [65] DEUZE J，BREON F-M，DESCHAMPS P, et al. Polarization measurements with the airborne version of the POLDER instrument[J]. Proceeding of SPIE，1992（1747）：178-187.

[66] [66] BREON F-M，DESCHAMPS P-Y. Optical and physical parameter retrieval from POLDER measurements over the ocean using an analytical model[J]. Remote Sens Environ，1993（43）：193-207.

[67] [67] LEROY M，LIFERMANN A. The POLDER instrument onboard ADEOS： scientific expectations and first results[J]. Adv Space Res，2000（25）：947-52.

[68] [68] TRAVIS L. Remote sensing of aerosols with the earth-observing scanning polarimeter[J]. 1992（1747）：154-164.

[70] [70] ANDERSON R. Polarized light examination and photography of the skin[J]. Arch Dermatol，1991（127）：1000.

[71] [71] JACQUES S, RAMELLA-ROMAN J, LEE K. Imaging skin pathology with polarized light[J]. 2002（7）：329-340.

[72] [72] HIELSCHER A H，MOURANT J R，BIGIO I J. Influence of particle size and concentration on the diffuse backscattering of polarized light from tissue phantoms and biological cell suspensions[J]. Appl Opt，1997，36（1）：125-35.

[73] [73] JARRY G，STEIMER E，DAMASCHINI V，et al. Coherence and polarization of light propagating through scattering media and biological tissues[J]. Appl Opt，1998，37（31）： 7357-67.

[74] [74] ROMAN J，JACQUES S L E D L T. Imaging of superficial tissues with polarized light：proceedings of the biomedical optical spectroscopy and diagnostics[C]//Optical Society of America，Miami Beach，Florida，2000，26（2）：119-29.

[75] [75] LU S-Y，CHIPMAN R A. Interpretation of mueller matrices based on polar decomposition[J]. J Opt Soc Am A，1996，13（5）：1106-13.

[76] [76] SCHECHNER Y，NARASIMHAN S G，NAYAR S K. Instant dehazing of images using polarization[M]. SPIE，2001.

[77] [77] MA H. Quantitative characterization of carcinoma tissues at different progression stages by Mueller matrix microscopy[C]//Proceedings of the Asia communications and photonics conference optical society of America，Guangzhou，Guangdong，2017.

[78] [78] SCHECHNER Y Y，NARASIMHAN S G，NAYAR S K. Polarization-based vision through haze[J]. Appl Opt，2003，42（3）：511-25.

[79] [79] SCHECHNER Y Y，KARPEL N. Clear underwater vision[C]//Proceedings of the 2004 IEEE Computer Society Conference on Computer Vision and Pattern Recognition，2004：1-1.

[80] [80] GILBERT G D，PERNICKA J C. Improvement of underwater visibility by reduction of backscatter with a circular polarization technique[J]. Appl Opt，1967，6（4）： 741-6.

[81] [81] TYO J S，ROWE M P，PUGH E N，et al. Target detection in optically scattering media by polarization-difference imaging[J]. Appl Opt，1996，35（11）：1855-70.

[82] [82] CARIOU J，LE JEUNE B，LOTRIAN J，et al. Polarization effects of seawater and underwater targets[J]. Appl Opt，1990，29（11）：1689-95.

[83] [83] LIU F，WEI Y，HAN P，et al. Polarization-based exploration for clear underwater vision in natural illumination [J]. Opt Express，2019，27（3）：3629-41.

[85] [85] LIU F，HAN P，WEI Y，et al. Deeply seeing through highly turbid water by active polarization imaging[J]. Opt Lett，2018，43（20）： 4903-6.

[86] [86] LIU F，CAO L，SHAO X，et al. Polarimetric dehazing utilizing spatial frequency segregation of images[J]. Applied Optics，2015，54（27）：8116-22.

[87] [87] HU H，ZHAO L，LI X，et al. Polarimetric image recovery in turbid media employing circularly polarized light [J]. Opt Express，2018，26（19）：25047-59.

[88] [88] HUANG B，LIU T，HU H，et al. Underwater image recovery considering polarization effects of objects[J]. Opt Express，2016，24（9）：9826-38.

[89] [89] TAO Q，SUN Y，SHEN F，et al. Active imaging with the aids of polarization retrieve in turbid media system[J]. Opt Commun，2016（359）：405-10.

[90] [90] XU Q，GUO Z，TAO Q，et al. Transmitting characteristics of polarization information under seawater[J]. Appl Opt，2015，54（21）：6584-8.

[91] [91] XU Q，GUO Z，QIANGQIANG T，et al. A novel method of retrieving the polarization qubits after being transmitted in turbid media[J]. J Opt，2015（17）：922-3.

[92] [92] D'ANGELO P，W HLER C. Image-based 3D surface reconstruction by combination of photometric，geometric，and real-aperture methods[J]. Isprs J Photogramm，2008（63）：297-321.

[93] [93] KADAMBI A，TAAMAZYAN V，SHI B，et al. Polarized 3D： high-quality depth sensing with polarization cues[M]. SPIE，2015.

[94] [94] HUANG X，BAI J，WANG K，et al. Target enhanced 3D reconstruction based on polarization-coded structured light [J]. Opt Express，2017，25（2）：1173-84.

[95] [95] KADAMBI A，TAAMAZYAN V，SHI B，et al. Polarized 3D： high-quality depth sensing with polarization cues[C]//IEEE International Conference on Computer Vision，2015：3370-3378.

[96] [96] LI Xuan，LIU Fei，HAN Pingli，et al. Near-infrared monocular 3D computational polarization imaging of surfaces exhibiting nonuniform reflectance[J]. Opt Express，2021，29（10）：15616-15630.

[97] [97] VOROBIEV D V，NINKOV Z，BROCK N. Astronomical polarimetry with the RIT polarization imaging camera[J]. Publ Astron Soc Pac，2018，130（988）： 064501.

[98] [98] WU F，YANG Y，JIANG J，et al. Classification between digs and dust particles on optical surfaces with acquisition and analysis of polarization characteristics[J]. Appl Opt，2019（58）：1073.

[99] [99] NATIV A，FELDMAN H，SHAKED N T. Wafer defect detection by a polarization-insensitive external differential interference contrast module[J]. Appl Opt，2018，57（13）：3534-8.

[100] [100] LEE B-H，IHM D-C，YEO J-H，et al. Polarization control for enhanced defect detection on advanced memory devices[M]. SPIE，2006.

[101] [101] GIAKOS G，FRAIWAN L，PATNEKAR N，et al. A sensitive optical polarimetric imaging technique for surface defects detection of aircraft turbine engines[J]. Instrumentation and Measurement，IEEE Transactions on，2004（53）：216-22.

[104] [104] JWA B，YI L B，SH B，et al. Ultrasensitive polarized-light photodetectors based on 2D hybrid perovskite ferroelectric crystals with a low detection limit[J]. Science Bulletin 2020（66）：158-163.

[105] [105] RUBIN N A，D'AVERSA G，CHEVALIER P，et al. Matrix Fourier optics enables a compact full-Stokes polarization camera[J]. Science，2019，365（6448）：eaax1839.