[2] X SHAO, X Q WU, F F YU et al. Characterization and monitoring of GOES-16 ABI stray light and comparison with Himawari-8 AHI and GOES-17 ABI. Journal of Applied Remote Sensing, 15, 017503(2021).

[3] S LEE, C Y CAO. Soumi NPP VIIRS day/night band stray light characterization and correction using calibration view data. Remote Sensing, 8, 138(2016).

[4] A F THERNISIEN, R A HOWARD, C KORENDYKE et al. Stray light analysis and testing of the SoloHI and WISPR heliospheric imagers, 10698(2018).

[5] D FROSTIG, J PIOTROWSKI, K CLARK et al. Stray light analysis and reduction for IFU spectrograph LLAMAS, 11447, 1446-1454(2020).

[6] A HAMMAR, O M CHRISTENSEN, W PARK et al. Stray light suppression of a compact off-axis telescope for a satellite-borne instrument for atmospheric research, 10815, 108150F(2018).

[7] Chao MEI. The study of stray light analysis and suppressing technology in large pupil mulit-spectal zoom optical system(2014).

[8] E MAZY, Y STOCKMAN, M-LHELLIN . Design and modelisation of a straylight facility for space optical instrument, 8550, 855007(2012).

[9] E C FEST. Stray light analysis and control(2013).

[10] M MONTANARO, A GERACE, A LUNSFORD et al. Stray light artifacts in imagery from the landsat 8 thermal infrared sensor. Remote Sensing, 6, 10435-10456(2014).

[11] Miaomiao ZHANG. Research on stray light characteristics and correction of directional polarimetric camera(2019).

[12] Zhile WANG, Zhongqiang GONG, Wei ZHANG et al. Measurement of stray light based on point-source transmittance in space optical system. Optical Technique, 37, 401-405(2011).

[13] Jianguo TIAN. Analysis and suppression of infrared stray light of geosynchronous orbiting telescope(2021).

[14] Yang WANG. Study on suppression and analysis of stray light in infrared detector assembly(2016).

[15] S RODNEY, L G STROLGER, P KELLY et al. SN refsdal: photometry and time delay measurements of the first einstein cross supernova. The Astrophysical Journal, 820, 1-18(2016).

[16] H E BOND, G H SCHAEFER, R L GILLILAND et al. The sirius system and its astrophysical puzzles: Hubble space telescope and ground-based astrometry. The Astrophysical Journal, 840, 1-17(2017).

[17] A L VERLAAN, H HOGENHUIS, J PIJNENBURG et al. LISA telescope assembly optical stability characterization for ESA, 10564, 105640K(2017).

[18] D WEISE, P MARENACI, P WEIMER et al. Opto-mechanical architecture of the LISA instrument, 10566, 1056611(2017).

[19] J C LIVAS, S R SANKAR. Optical telescope system-level design considerations for a space-based gravitational wave mission, 9904, 99041K(2016).

[20] Y GONG, J LUO, B WANG. Concepts and status of Chinese space gravitational wave detection projects. Nature Astronomy, 5, 881-889(2021).

[21] W H RUAN, Z K GUO, R G CAI et al. Taiji program: gravitational-wave sources. International Journal of Modern Physics A, 35, 2050075(2020).

[22] W SUTHERLAND, J EMERSON, G DALTON et al. The visible and infrared survey telescope for astronomy (VISTA): design, technical overview, and performance. Astronomy & Astrophysics, 575, A25(2015).

[23] X ZHONG, Z SU, G ZHANG et al. Analysis and reduction of solar stray light in the nighttime imaging camera of Luojia-1 satellite. Sensors, 19, 1130(2019).

[24] Hu WANG, Liquan WU, Yaoke XUE et al. A horn tube type baffle.

[25] V ABBASI, S THORSTEINSON, D BALAM et al. The NEOSSat experience: 5 years in the life of Canada’s space surveillance telescope, 22, 1-16(2019).

[26] Zhiqiang WANG. Design of off-axis reflecting collimator with 350mm aperture(2020).

[27] Linglin WU, Zhonghua MIAO, Hongli BAI et al. A honeycomb baffle.

[28] Yulin HE, Senyang HE. A honeycomb anti-glare optical component and classroom lighting fixture.

[29] Xue CHEN, Chuang SUN, Xinlin XIA. Stray light suppression property of baffle with honeycombed wall. Acta Optica Sinica, 32, 230-234(2012).

[30] Tao YANG, Chunlin LI, Qingliang MENG. Application of reflective ellipsoid grating system in space optical remote sensor. Spacecraft Recovery & Remote Sensing, 37, 74-81(2016).

[31] G L PETERSON, S C JOHNSTON, J THOMAS. Specular baffles, 1753, 65-76(1993).

[32] E SCHNEIDER. Thermal design of retroreflective stray light fore-baffles for spaceborne optical systems, 4198, 82-95(2001).

[33] Qiang LU. Study on stray light analysis and application technology of the earth synchronous orbit space camera(2016).

[34] M SHOLL, F GROCHOCKI, J FLEMING et al. Stray light design and analysis of the SNAP telescope, 6675, 66750C(2007).

[35] S LIN, H WANG, Y LIU et al. Research on stray light suppression of space debris detection camera, 11341, 113410O(2019).

[36] Shangmin LIN, Hu WANG, Jie LIU et al. A telescopic expandable mechanism.

[37] S M LIN, H WANG, Y LIU et al. Athermalization for the supporting structure of space camera primary and secondary mirrors, 11052, 110520U(2019).

[38] H KAWANO, Y SATO, K MITANI et al. New light-shielding technique for shortening the baffle length of a star sensor, 4767, 62-69(2002).

[39] H KAWANO, H SHIMOJI, S YOSHIKAWA et al. Solar-light shielding using a near-hemispherical lens for a star sensor. Optical Engineering, 45, 124403(2006).

[40] P A WARREN, M J SILVER, JR B J DOBSON et al. Experimental characterization of deployable outer barrel assemblies for large space telescopes, 8860, 49-61(2013).

[41] J W ARENBERG, J ADAMSON, G HARPOLE et al. Determination of emissivities of key thermo-optical surfaces on the James Webb Space Telescope, 9143, 1113-1122(2014).

[42] P A LIGHTSEY, Z WEI. James Webb Space Telescope stray light performance status update, 8442, 84423B(2012).

[43] M R BOLCAR, K BALASUBRAMANIAN, M CLAMPIN et al. Technology development for the advanced technology large aperture space telescope (ATLAST) as a candidate large UV-optical-infrared (LUVOIR) surveyor, 9602, 86-99(2015).

[44] H TANG, J XIE, X TANG et al. On-orbit radiometric performance of GF-7 satellite multispectral imagery. Remote Sensing, 14, 886(2022).

[45] J YAO, X TANG, G LI et al. Cloud detection of GF‐7 satellite laser footprint image. IET Image Processing, 15, 2127-2134(2021).

[46] L LIU, J XIE, X TANG et al. Coarse-to-fine image matching-based footprint camera calibration of the GF-7 satellite. Sensors, 21, 2297(2021).

[47] N ZHOU, C LI, W GAO et al. A secondary mirror adjustment system with hexapod structure for optical telescope application, 9280, 92800N(2014).

[48] P ZHONG, C LI, N JING et al. Research on lightweight passive deployment mechanism for the secondary mirror in the deployable space telescope, 9685, 968513(2016).

[49] C ZHAO, C LI, N ZHOU et al. Self-deployable structure designed for space telescope for microsatellite application, 9685, 96850B(2016).

[50] H DAI, C LI, L LI et al. Design of deployment systems for high-resolution deployable telescope based on CubeSat, 12069, 1206918(2021).

[51] W LEI, C LI, P ZHONG et al. Realization and testing of a deployable space telescope based on tape springs, 10339, 1033920(2017).

[52] Y LIAN, Z HUO, Y CHENG. On the dynamics and control of the sun-earth L2 tetrahedral formation. Astrodynamics, 5, 331-346(2021).

[53] Zhaoyuan TONG, Meng LI, Chengbo CUI et al. Design and analysis of the configuration of deployable membrane sunshield. Chinese Space Science and Technology, 41, 82-88(2021).

[54] D WEBB, B HIRSCH, V BACH et al. Starshade mechanical architecture & technology effort, 2165(2016).

[55] D WEBB, M ARYA, S BRADFORD et al. Advances in starshade technology readiness for an exoplanet characterizing science mission in the 2020’s, 11117, 111170P(2019).

[56] D WEBB, B HIRSCH, C BRADFORD et al. Advances in starshade technology readiness for an exoplanet characterizing science mission in the 2020’s, 9912, 99126H(2016).

[57] D KLING, S K JEON, J BANIK. Novel folding methods for deterministic deployment of common space structures, 2168(2016).

[58] P SANDRI, S FINESCHI, M ROMOLI et al. Stray-light analyses of the multielement telescope for imaging and spectroscopy coronagraph on Solar Orbiter. Optical Engineering, 57, 015108(2018).

[59] Peipei YAN. Research on stray radiation suppression of dual band integrative optical system used to low-orbit spaceborne earth(2019).

[60] Mingzhe SUN, Hongxin ZHANG, Zhenwu LU et al. Stray light suppression of the large field of view coronagraph optical system. Laser & Optoelectronics Progress, 51, 162-168(2014).

[61] M SUN, H ZHANG, H BU et al. Computation of the diffracted field of a toothed occulter by the semi-infinite rectangle method. Journal of Optical Society of America A, 30, 2140-2149(2013).

[62] Jianxian ZHANG, Yongjun ZOU, Lei XU et al. Matte coating and its application in optical system. Aerospace Materials and Technology, 44, 88-90(2014).

[64] M R DURY, T THEOCHAROUS, N HARRISON et al. Common black coatings-reflectance and ageing characteristics in the 0.32–14.3 μm wavelength range. Optics Communications, 270, 262-272(2007).

[66] C M ALMEIDA, M E GHICA, A L RAMALHO et al. Silica-based aerogel composites reinforced with different aramid fibres for thermal insulation in Space environments. Journal of Materials Science, 56, 13604-13619(2021).

[67] Y TULEUSHEV, V VOLODIN, E ZHAKANBAEV et al. Fabrication of porous tantalum and tungsten black coatings for artificial earth satellites. Technical Physics Letters, 46, 319-322(2020).

[68] Liang XU. Research on key technologies of stray light measurement for large aperture optical system(2019).

[69] Y LIU, J HUANG, X FENG et al. Thermal-sprayed photocatalytic coatings for biocidal applications: a review. Journal of Thermal Spray Technology, 30, 1-24(2021).

[70] C YANG, J LIU, Q REN et al. Development of novel thermal sprayed hydroxyapatite-rare earth (HA-Re) coatings for potential antimicrobial applications in orthopedics. Journal of Thermal Spray Technology, 30, 886-897(2021).

[71] D FANG, Y ZHENG, B ZHANG et al. Automatic robot trajectory for thermal-sprayed complex Surfaces. Advances in Materials Science and Engineering, 2018, 1-11(2018).

[73] Y FU, Y LIU, H LI. Efficient coating fabrication of onion-like carbon nanoparticles via aerosol deposition. Particuology, 53, 58-62(2020).

[74] Jiaqiang ZHANG, Hu NIU, Youjian YANG et al. Effect of deep space radiation environments on properties of high absorptivity stray light coatings. Aerospace Materials and Technology, 51, 134-138(2021).

[75] Tuo PING, Ying ZHOU, Chengwu YU et al. Effect of simulated space radiation environments on properties of stray light coatings. Surface Technology, 49, 30-37(2020).

[76] S S SIWAL, A K SAINI, S RAROTRA et al. Recent advancements in transparent carbon nanotube films: chemistry and imminent challenges. Journal of Nanostructure in Chemistry, 11, 93-130(2021).

[77] L ZHANG, X WANG, W XU et al. Strong and conductive dry carbon nanotube films by microcombing. Small, 11, 3830-3836(2015).

[78] I N KHOLMANOV, C W MAGNUSON, R PINER et al. Optical, electrical, and electromechanical properties of hybrid graphene/carbon nanotube films. Advanced Materials, 27, 3053-3059(2015).

[80] J T RICHELSON. Satellite in the shadows. Bulletin of the Atomic Scientists, 61, 26-33(2005).

[81] Meizi XIAO. “Keyhole” junior debuts. Space Exploration, 46-49(2019).

[83] F DE NICOLA, P HINES, M DE CRESCENZI et al. Moth-eye effect in hierarchical carbon nanotube anti-reflective coatings. Carbon, 108, 262-267(2016).

[84] Yuncai HAO, Chengwu YU, Shitong LIANG et al. New generation of star tracker baffle-CNT baffle. Aerospace Control and Application, 42, 1-7+31(2016).

[85] X LI, M LI, H LIU. Effective strategy to achieve a metal surface with ultralow reflectivity by femtosecond laser fabrication. Chinese Optics Letters, 19, 051401(2021).

[86] X LI, M LI, H LIU. Enhanced optical absorption surface of titanium fabricated by a femtosecond laser assisted with airflow pressure. Chinese Optics Letters, 19, 091404(2021).

[88] Yongqiang PAN, Zhensen WU, Lingxia HANG. Optical thin films interfaces roughness cross-correlated properties and light scattering. Chinese Journal of Lasers, 35, 916-920(2008).

[89] L HANG, W LIU, J XU et al. Effects of various substrate materials on microstructural and optical properties of amorphous silicon oxynitride thin films deposited by plasma-enhanced chemical vapor deposition. Thin Solid Films, 709, 138186(2020).

[90] K YI, D LIU, X CHEN et al. Plasma-enhanced chemical vapor deposition of two-dimensional materials for applications. Accounts of Chemical Research, 54, 1011-1022(2021).

[91] Y HAMEDANI, P MACHA, T J BUNNING et al. Plasma-enhanced chemical vapor deposition: where we are and the outlook for the future(2016).

[92] Qibiao ZGOU, Jianhua CHEN, Yuhua SONG et al. Design and analysis of variable refractivity optical film. New Technology & New Process, 47-51(2020).

[93] Liangyi HANG, Weiguo LIU, Lingxia HANG et al. Research progress in preparation of optical thin films by PECVD. Laser & Optoelectronics Progress, 57, 45-56(2020).

[94] J Q XI, M F SCHUBERT, J K KIM et al. Optical thin-film materials with low refractive index for broadband elimination of Fresnel reflection. Nature Photonics, 1, 176-179(2007).

[95] J E HARVEY, N CHOI, S SCHROEDER et al. Total integrated scatter from surfaces with arbitrary roughness, correlation widths, and incident angles. Optical Engineering, 51, 013402(2012).

[96] L DOYKE, P KHADEMI, P HILZ et al. Experimental estimates of the photon background in a potential light-by-light scattering study. New Journal of Physics, 24, 025003(2022).

[97] J DING, Z CAI, J X PROCHASKA et al. Deep Hubble space telescope imaging on the extended Lyα emission of a QSO at z=2.19 with a damped lyman alpha system as a natural coronagraph. The Astrophysical Journal Letters, 889, L12(2020).

[98] A FEDOTOV. Getting rid of 95% UCL calculations in ISO 14644-1: 2015 standard: new weaknesses and possible solutions. Clean Air and Containment Review, 2018, 12-15(2018).

[99] D ENSOR, A M DIXON, R BURROWS. IEST leads development of first ISO 14644 nanotechnology standard. Journal of the IEST, 59, 1-3(2016).

[100] T LIU, X LI, M XU et al. Design a pediatric isolation bed and characterization of its purification efficacy in ambient air. Biosafety and Health, 3, 172-178(2021).

[101] K W CALABRO, M ZOLLERS. Effects of individual particulates in optical systems using a spatially isolated contamination scattering method, 11105, 1110509(2019).

[102] B MA, Z SHEN, P HE et al. Evaluation and analysis of polished fused silica subsurface quality by the nanoindenter technique. Applied Optics, 50, 279-285(2011).

[103] K BALASUBRAMANIAN, S SHAKLAN, A GIVEON. Stellar coronagraph performance impact due to particulate contamination and scatter, 7440, 74400T(2009).

[104] V KHODNEVYCH, M LINTZ, J N DINU et al. Stray light estimates due to micrometeoroid damage in space optics, application to the LISA telescope. Journal of Astronomical Telescopes, Instruments, and Systems, 6, 048005(2020).

[105] Weirong YANG, Yongqiang PAN, Zhiqi ZHENG. Single-layer film regulation characteristics of particle pollutant scattering from optical surfaces. Infrared and Laser Engineering, 50, 465-471(2021).

[106] Jinze LIU, Yongqiang PAN, Chen YANG. Theoretical and experimental study on scattering reduction of single-layer TiO2/SiO2 optical films. Surface technology, 48, 172-176(2019).

[107] L K RANDENIYA, G J DE GROOT. Non-thermal plasma treatment of agricultural seeds for stimulation of germination, removal of surface contamination and other benefits: a review. Plasma Processes and Polymers, 12, 608-623(2015).

[108] A HEYA, T HARADA, M NIIBE et al. Removal of surface contamination by atomic hydrogen annealing. Journal of Photopolymer Science and Technology, 33, 419-426(2020).

[109] R ROTH, S COEMERT, S BURKHARDT et al. A process towards eliminating cytotoxicity by removal of surface contamination from electrical discharge machined nitinol. Procedia CIRP, 89, 45-51(2020).

[110] R SHERMAN. Carbon dioxide snow cleaning applications(2019).

[111] L MASKOVA, J SMOLIK, P VAVROVA et al. Carbon dioxide snow cleaning of paper. Heritage Science, 9, 1-15(2021).

[112] Hu WANG, Jie LIU, Shangmin LIN et al. A dustproof device for an optical system.

[113] Meidan ZHAI, Junfeng MI, Wenxin MA et al. The development of electrostatic dust removal technology and its influencing factors. Applied Chemical Industry, 50, 2572-2577(2021).

[114] Z FENG, Z LONG, T YU. Filtration characteristics of fibrous filter following an electrostatic precipitator. Journal of Electrostatics, 83, 52-62(2016).

[115] Jun PENG. Analysis and measurement of iinternal stray radiation of thermal infrared imaging spectrometer(2020).

[116] M DOLCI, A VALENTINI, M RAGNI et al. AMICA at Dome C: results from the first year of automatic operation tests in Antarctica, 8446, 1406-1419(2012).

[117] Z LIU, J XU, B Z GU et al. New vacuum solar telescope and observations with high resolution. Research in Astronomy and Astrophysics, 14, 705(2014).

[118] A H ALHAMEDI, R J LILLIS, A R POPPE et al. TRACE: telescope for radiation characterization at Europa(2018).

[119] M KARPENKO, S BHATT, N BEDROSSIAN et al. Flight implementation of pseudospectral optimal control for the TRACE space telescope, 6506(2011).

[120] P CHEIMETS, D C CALDWELL, C CHOU et al. SDO-AIA telescope design, 7438, 141-152(2009).

[121] Weian ZHANG, Xiaojie YANG, Zhongliang ZHOU. Study on suppressing false signal generated by sunlight in omni-directional laser detection. Electro-Optic Technology Application, 26, 55-58(2011).

[122] H GUO, Q CHEN, N MA et al. Test and analysis of background sunlight's influence on laser receiver, 10457, 104570K(2017).

[123] Liming YANG. Study of target enhancement technique based on polarimetric imaging(2018).

[124] Xiaopeng SHAO, Fei LIU, Wei LI et al. Latest progress in computational imaging technology and application. Laser & Optoelectronics Progress, 57, 11-55(2020).

[125] H HU, L ZHAO, X LI et al. Polarimetric image recovery in turbid media employing circularly polarized light. Optics Express, 26, 25047-25059(2018).

[126] F LIU, Y WEI, P HAN et al. Polarization-based exploration for clear underwater vision in natural illumination. Optics Express, 27, 3629-3641(2019).

[127] P HAN, F LIU, K YANG et al. Active underwater descattering and image recovery. Applied Optics, 56, 6631-6638(2017).

[128] Hu WANG, Zehua MA, Yang SHEN et al. A large field of view energy detection optical system based on concentric spherical mirrors.

[129] Tengfei ZHANG. Study on stray light characteristic analysis and correction method of watercolor image spectrometer(2016).

[130] B BITLIS, P A JANSSON, J P ALLEBACH. Parametric point spread function modeling and reduction of stray light effects in digital still cameras, 6498, 253-260(2007).

[131] G KOVACS, H SIERKS, A NATHUES et al. Stray light calibration of the dawn framing camera, 8889, 239-246(2013).

[132] W XU, J GONG, M WANG. Development, application, and prospects for Chinese land observation satellites. Geo-spatial Information Science, 17, 102-109(2014).

[133] Y KANG, L PAN, M SUN et al. Destriping high-resolution satellite imagery by improved moment matching. International Journal of Remote Sensing, 38, 6346-6365(2017).

[134] Ming YAN, Fei WU, Zhiyong WANG. Removal of SJ-9A optical imagery stray light stripe noise. Spacecraft Recovery& Remote Sensing, 35, 72-80(2014).

[135] Y ZONG, S W BROWN, G MEISTER et al. Characterization and correction of stray light in optical instruments, 6744, 422-432(2007).

[136] S D BUTLER, S E NAUYOKS, M A MARCINIAK. Comparison of microfacet BRDF model elements to diffraction BRDF model elements, 9472, 94720C(2015).

[137] S D BUTLER, S E NAUYOKS, M A MARCINIAK. Comparison of microfacet BRDF model to modified Beckmann-Kirchhoff BRDF model for rough and smooth surfaces. Optics Express, 23, 29100-29112(2015).

[138] Xiaochen ZHAO. Technological research of the scattered light measurement of optical element of the surface in solar telescope system(2016).

[139] T HALLBERG, D A PEARCE, P RAVEN et al. Round robin comparison of BRDF measurements, 11158, 111580I(2019).

[140] T HALLBERG, A POHL, J FAGERSTRöM. Simplifying BRDF input data for optical signature modeling, 10206, 102060V(2017).

[141] T ARTS, D TOMUTA, V KIRSCHNER. Black coatings BSDF database, 11852, 1185261(2021).

[142] M KRONEBERGER, A MEZGER, J B VOLATIER. Scattering from reflective diffraction gratings: the challenges of measurement and verification, 10692, 106920G(2018).

[143] D GUARNERA, G C GUARNERA, A GHOSH et al. BRDF representation and acquisition. Computer Graphics Forum, 35, 625-650(2016).

[144] N ANTHONY, J FROSTEVARG, H SUHONEN et al. Laser processing of minerals common on asteroids. Optics & Laser Technology, 135, 106724(2021).

[145] Chengcheng LI. Analysis and experimental study of laser scattering characteristics based of kirchhoff approximation(2021).

[146] J Y XUE, Y H CAO, Z S WU et al. Multiple scattering and modeling of laser in fog. Chinese Physics B, 30, 336-344(2021).

[147] J ZHU, K WANG, H LIU et al. Modified model of polarized bidirectional reflectance distribution function for metallic surfaces. Optics & Laser Technology, 99, 160-166(2018).

[148] K WANG, J ZHU, H LIU et al. Expression of the degree of polarization based on the geometrical optics pBRDF model. Journal of Optical Society of America A, 34, 259-263(2017).

[149] W ZHANG, J ZHAO, L LIU. Experimental study of the effective BRDF of a copper foam sheet(2013).

[150] Y LIU, K YU, Z LIU et al. Polarized BRDF measurement of steel E235B in the near-infrared region: based on a self-designed instrument with absolute measuring method. Infrared Physics & Technology, 91, 78-84(2018).

[151] K ZHANG, W HUANG, B ZHANG et al. Application of first-order nonparaxial scalar theory to determine surface scattering intensity of multilayer optical coatings. Optics Express, 26, 34592-34608(2018).

[152] F SHEIKH, T KAISER. A modified Beckmann-Kirchhoff scattering model for slightly rough surfaces at terahertz frequencies, 2079-2080(2019).

[153] I OHLIDAL, J VOHANKA, M CERMAK et al. Combination of spectroscopic ellipsometry and spectroscopic reflectometry with including light scattering in the optical characterization of randomly rough silicon surfaces covered by native oxide layers. Surface Topography: Metrology and Properties, 7, 045004(2019).

[154] Y IGARASHI, T MITSUNARI, K YAMAZAKI. Surface roughness measurement using the generalized Harvey-Shack scattering theory and the K-correlation model, 11782, 117821S(2021).

[155] F SHEIKH, Y GAO, T KAISER. A study of diffuse scattering in massive MIMO channels at terahertz frequencies. IEEE Transactions on Antennas and Propagation, 68, 997-1008(2019).

[156] J E HARVEY. Understanding surface scatter: a linear systems formulation(2019).

[157] J C STOVER. Optical scattering: measurement and analysis(2012).

[158] T AKUTSU, M ANDO, K ARAI et al. Overview of KAGRA: KAGRA science. Progress of Theoretical and Experimental Physics, 2021, 05A103(2021).

[159] S D SHIBAIKIN, E G ALEKSEEV. Software library for the lighting fixtures optical characteristics calculation by the computer-aided design system kompas 3D. Light & Engineering, 29, 78-85(2021).

[160] R T TAN. Specularity, specular reflectance. Computer Vision: A Reference Guide, 1-4(2020).

[161] M BITTERLING, G BERN, P SCHOTTL et al. Measuring and modelling the BRDF of solar receiver paints, 2303, 030006(2020).

[162] Y LIU, J DAI, S ZHAO et al. Optimization of five-parameter BRDF model based on hybrid GA-PSO algorithm. Optik, 219, 164978(2020).

[163] L BAI, Z WU, X ZOU et al. Seven-parameter statistical model for BRDF in the UV band. Optics Express, 20, 12085-12094(2012).

[164] Z JIAO, A DING, A KOKHANOVSKY et al. Development of a snow kernel to better model the anisotropic reflectance of pure snow in a kernel-driven BRDF model framework. Remote sensing of environment, 221, 198-209(2019).

[165] T SUN, H W JENSEN, R RAMAMOORTHI. Connecting measured BRDFs to analytic BRDFs by data-driven diffuse-specular separation. ACM Transactions on Graphics (TOG), 37, 1-15(2018).

[166] Y LIU, J DAI, S ZHAO et al. A bidirectional reflectance distribution function model of space targets in visible spectrum based on GA-BP network. Applied Physics B, 126, 1-9(2020).

[167] T DAHMEN, P TRAMPERT, F BOUGHORBEL et al. Digital reality: a model-based approach to supervised learning from synthetic data. AI Perspectives, 1, 1-12(2019).

[168] R FURFARO, R LINARES, V REDDY. Space objects classification via light-curve measurements: deep convolutional neural networks and model-based transfer learning(2018).

[169] Dun LIU. Research on stray light in hybrid diffractiove/ refractive imaging optical system(2018).

[170] J G TIAN, X L LI, L B HOU et al. Analysis and suppression of stray radiation in an infrared telescope system in geosynchronous orbit, 11548, 115480I(2020).

[171] Xingxing SHU. Analysis and suppression of stray light in visible light optical system(2015).

[172] D LIU, L WANG, W YANG et al. Stray light characteristics of the diffractive telescope system. Optical Engineering, 57, 025105(2018).

[173] Zhaohui LI. Stray light testing technology research of long focal length and large aperture optical system(2016).

[174] Xiaoping LI, Gang WANG, Tingliang HU. High-precision stray light measurement system analysis. Infrared Technology, 33, 521-524(2011).

[175] Zhen MA, Xuewu FAN, Rongli CHEN et al. Large aperture stray light coefficient measurement method and system based on computer holographic optical components.

[176] Liang XU, Jianke ZHAO, Yan ZHOU et al. Large aperture stray light test device and test method.

[177] J FLEMING, F GROCHOCKI, T FINCH et al. New stray light test facility and initial results, 7069, 70690O(2008).

[178] G FRANK, F JOHN. Stray light testing of the OLI telescope, 7794, 77940W(2010).

[179] Q F CHEN, Z MA, X LI et al. Stray light measurement for point source transmittance of space optical systems, 9684, 726-732(2016).

[180] Qinfang CHEN, Yaoke XUE, Yang LI et al. A high rejection ratio optical trap.

[181] Qinfang CHEN, Yaoke XUE, Zhanpeng MA et al. Stray light test system test chamber glass.

[182] Qinfang CHEN, Yaoke XUE, Zhanpeng MA et al. Device and method for aligning the optical axis of the collimator with the optical axis of the optomechanical system in the stray light test.

[183] Z P MA, Q F CHEN, H WANG. Simulation and analysis of atmospheric scattering in stray light testing for point source transmittance. Applied Optics, 60, 232-238(2021).

[184] Qinfang CHEN, Liang XU, Jiaoteng DING et al. A time-resolved point source transmittance stray light measurement system.

[185] Y STOCKMAN, L ABALLEA, A BAEKE et al. Stray light testing of the PROBA V payload, 8889, 228-238(2013).

[186] G L PETERSON. Stray light test station for measuring point source transmission and thermal background of visible and infrared sensors, 7069, 208-216(2008).

[187] Hui LI. Study on the stray light analysis method for optical system(1996).

[188] Yuncai HAO. Technical progress and application of space optical sensor. Aerospace Control and Application, 43, 9-18(2017).