[1] L WANG, P P HO, C LIU et al. Ballistic 2-D imaging through scattering walls using an ultrafast optical Kerr Gate. Science, 253, 769-771(1991).

[2] G E ANDERSON, F LIU, R R ALFANO. Microscope imaging through highly scattering media. Optics Letters, 19, 981-983(1994).

[3] S KANG, S JEONG, W CHOI et al. Imaging deep within a scattering medium using collective accumulation of single - scattered waves. Nature Photonics, 9, 253-258(2015).

[4] J GUAN, Y CHENG, G CHANG. Time-domain polarization difference imaging of objects in turbid water. Optics Communication, 391, 82-87(2017).

[5] Y ZHOU, H XIA, X WANG et al. Study on label-free cell detection and classification method by using spectral decomposition-based dynamic scattering imaging. Journal of Electronic Measurement and Instrumentation, 36, 42-47(2022).

[6] Z FAN, J WANG, K YANG et al. Underwater polarization descattering imaging method based on adaptive background light extraction (Invited). Electro-Optic Technology Application, 38, 42-49(2023).

[7] HU Tianqi. Simulation of the perfmance of scintillation detect f the Muon scattering imaging [D]. Hefei: University of Science Technology of China, 2020. (in Chinese)

[8] Y ZHENG, W TAN, X LIU et al. Ballistic imaging through an intense scattering medium using a supercontinuum with a roundabout spatial gate. Optics Express, 25, 20431-20436(2017).

[9] Y ZHENG, C ZHU, F ZHAO et al. Ballistic imaging through an intense scattering medium using a subtractive optical Kerr gate. Infrared Physics & Technology, 116, 103767(2021).

[10] J S TYO, M P ROWE, E N PUGH et al. Target detection in optically scattering media by polarization-difference imaging. Applied Optics, 35, 1855-1870(1996).

[11] C GAO, M ZHAO, F CAO et al. Underwater polarization de-scattering imaging based on orthogonal polarization decomposition with low-pass filtering. Optics and Lasers in Engineering, 170, 107796(2023).

[12] S FENG, C KANE, P A LEE et al. Correlations and fluctuations of coherent wave transmission through disordered media. Physical Review Letters, 61, 834(1988).

[13] T SHI, L LI, H CAI et al. Computational imaging of moving objects obscured by a random corridor via speckle correlations. Nature Communications, 13, 4081(2022).

[14] F ZHAO, Y HU, P WANG et al. Polarization multiplexing scattering imaging. Acta Physica Sinica, 72, 154201(2023).

[15] M CHO, B JAVIDI. Peplography—a passive 3D photon counting imaging through scattering media. Optics Letters, 41, 5401-5404(2016).

[16] F HE, R LIU, X TIAN. Scanning-based photon-limited imaging through scattering media. Optics and Lasers in Engineering, 161, 107388(2023).

[17] Z YAQOOB, D PSALTIS, M S FELD et al. Optical phase conjugation for turbidity suppression in biological samples. Nature Photonics, 2, 110-115(2008).

[18] C L HSIEH, Y PU, R GRANGE et al. Digital phase conjugation of second harmonic radiation emitted by nanoparticles in turbid media. Optics Express, 18, 12283-12290(2010).

[19] I M VELLEKOOP, A P MOSK. Focusing coherent light through opaque strongly scattering media. Optics Letters, 32, 2309-2311(2007).

[20] R HORSTMEYER, H RUAN, C YANG. Guidestar-assisted wavefront shaping methods for focusing light into biological tissue. Nature Photonics, 9, 563-571(2015).

[21] I M VELLEKOOP. Feedback-based wavefront shaping. Optics Express, 23, 12189-12206(2015).

[22] H YU, J PARK, K LEE et al. Recent advances in wavefront shaping techniques for biomedical applications. Current Applied Physics, 15, 632-641(2015).

[23] S ROTTER, S GIGAN. Light fields in complex media: Mesoscopic scattering meets wave control. Reviews of Modern Physics, 89, 015005(2017).

[24] D B CONKEY, A M CARAVACA-AGUIRRE, R PIESTUN. High-speed scattering medium characterization with application to focusing light through turbid media. Optics Express, 20, 1733-1740(2012).

[25] PUTTEN E G VAN, D AKBULUT, J BERTOLOTTI et al. Scattering lens resolves sub -100 nm structures with visible light. Physical Review Letters, 106, 193905(2011).

[26] J H PARK, C PARK, H S YU et al. Subwavelength light focusing using random nanoparticles. Nature Photonics, 7, 454-458(2013).

[27] C PARK, J H PARK, C RODRIGUEZ et al. Full-field subwavelength imaging using a scattering superlens. Physical Review Letters, 113, 113901(2014).

[28] J R FIENUP. Reconstruction of an object from the modulus of its Fourier transform. Optics Letters, 3, 27-29(1978).

[29] J R FIENUP. Phase retrieval algorithms: a comparison. Applied Optics, 21, 2758-2769(1982).

[30] M CUI, C YANG. Implementation of a digital optical phase conjugation system and its application to study the robustness of turbidity suppression by phase conjugation. Optics Express, 18, 3444-3455(2010).

[31] T R HILLMAN, T YAMAUCHI, W CHOI et al. Digital optical phase conjugation for delivering two-dimensional images through turbid media. Scientific Reports, 3, 1909(2013).

[32] B LIU, Z YANG, S QU et al. Influence of turbid media at different locations in computational ghost imaging. Acta Optica Sinica, 36, 197-205(2016).

[33] M LE, G WANG, H ZHENG et al. Underwater computational ghost imaging. Optics Express, 25, 22859-22868(2017).

[34] Z GAO, X CHENG, L ZHANG et al. Compressive ghost imaging in scattering media guided by region of interest. Journal of Optics, 22, 055704(2020).

[35] T ANDO, R HORISAKI, J TANIDA. Speckle-learning-based object recognition through scattering media. Optics Express, 23, 33902-33910(2015).

[36] R HORISAKI, R TAKAGI, J TANIDA. Learning-based imaging through scattering media. Optics Express, 24, 13738-13743(2016).

[37] K HORNIK, M STINCHCOMBE, H WHITE. Multilayer feedforward networks are universal approximators. Neural Networks, 2, 359-366(1989).

[38] S POPOFF, G LEROSEY, R CARMINATI et al. Measuring the transmission matrix in optics: an approach to the study and control of light propagation in disordered media. Physical Review Letters, 104, 100601(2010).

[39] E N LEITH, J UPATNIEKS. Holographic imagery through diffusing media. Journal of the Optical Society of America, 56, 523(1966).

[40] A P MOSK, A LAGENDIJK, G LEROSEY et al. Controlling waves in space and time for imaging and focusing in complex media. Nature Photonics, 6, 283-292(2012).

[41] M LYU, H WANG, G LI et al. Learning-base lensless imaging through optically thick scattering media. Advanced Photonics, 1, 036002(2019).

[42] S LI, M DENG, J LEE et al. Imaging through glass diffusers using densely connected convolutional networks. Optica, 5, 803-813(2018).

[43] Y LI, Y XUE, L TIAN. Deep speckle correlation: a deep learning approach toward scalable imaging through scattering media. Optica, 5, 1181-1190(2018).

[44] S BIANCHI, LEONARDO R DI. A multi-mode fiber probe for holographic micromanipulation and microscopy. Lab on a Chip, 12, 635-639(2012).

[45] Z GAO, X CHENG, J YUE et al. Extendible ghost imaging with high reconstruction quality in strong scattering medium. Optics Express, 30, 45759-45775(2022).

[46] K CHEN, H XIAO, X CHENG et al. Computational ghost imaging with PSF-guiding deep learning through various unknown turbid scattering media. Journal of Optics, 24, 115603(2022).

[47] B LIN, X FAN, Z GUO. Self-attention module in a multi-scale improved U-net (SAM-MIU-net) motivating high-performance polarization scattering imaging. Optics Express, 31, 3046-3058(2023).

[48] LIN B, FAN X, LI D, et al. Highperfmance polarization imaging reconstruction in scattering system under natural light conditions with an improved U[C]Photonics. MDPI, 2023, 10(2): 204.

[49] C XU, D LI, X FAN et al. High-performance deep-learning based polarization computational ghost imaging with random patterns and orthonormalization. Physica Scripta, 98, 065011(2023).

[50] B LIN, X FAN, P PENG et al. Dynamic polarization fusion network (DPFN) for imaging in different scattering systems. Optics Express, 32, 511-525(2023).