[1] Cigui LIU. Resolutely shouldering the historic mission of building a maritime power. Qiushi, 15, 20-22(2016).

[2] Jiejun WANG, Lei LIANG, Shu LI et al. Correction and implement of polarization-difference imaging model for underwater target. Acta Optica Sinica, 39, 160-166(2019).

[3] R C SMITH, K S BAKER. Optical properties of the clearest natural waters (200-800 nm). Applied Optics, 20, 177-184(1981).

[4] Yi WEI, Fei LIU, Kui YANG et al. Passive underwater polarization imaging detection method in neritic area. Acta Physica Sinica, 67, 115-124(2018).

[5] B L MCGLAMERY. A computer model for underwater camera systems(1980).

[6] Yan HU. Research on underwater image restoration(2019).

[7] K XU, J L BA, R KIROS et al. Show, attend and tell: neural image caption generation with visual attention, 2048-2057(2015).

[8] J HU, L SHEN, S ALBANIE et al. Squeeze-and-excitation networks. IEEE Transactions on Pattern Analysis and Machine Intelligence, 42, 2011-2023(2020).

[9] M JADERBERG, K SIMONYAN, A ZISSERMAN et al. Spatial transformer networks, 2017-2025(2015).

[10] Cong WANG. Research on underwater image enhancement algorithm(2021).

[11] Xinwei WANG, Liang SUN, Minmin WANG et al. Deblurring methods for underwater 2D and 3D range-gated imaging. Infrared and Laser Engineering, 49, 27-37(2020).

[12] Yan WANG. Research on underwater image enhancement methods based on image formation model(2019).

[13] Dongmei HUANG, Yan WANG, Wei SONG et al. Underwater image enhancement method using adaptive histogram stretching in different color models. Journal of Image and Graphics, 23, 640-651(2018).

[14] Y WANG, W SONG, G FORTINO et al. An experimental-based review of image enhancement and image restoration methods for underwater imaging. IEEE Access, 7, 140233-140251(2019).

[15] I KASHIF, R A SALAM, O AZAM et al. Underwater image enhancement using an integrated colour model. Iaeng International Journal of Computer Science, 34, 239-244(2007).

[16] Leibo LAN. Research on color image enhancement in underwater scattering media(2015).

[17] S VASAMSETTI, N MITTAL, B C NEELAPU et al. Wavelet based perspective on variational enhancement technique for underwater imagery. Ocean Engineering, 141, 88-100(2017).

[18] Wen WANG. Research on underwater image enhancement based on multi-scale fusion(2019).

[19] C O ANCUTI, C ANCUTI, C D VLEESCHOUWER et al. Color balance and fusion for underwater image enhancement. IEEE Transactions on Image Processing, 27, 379-393(2018).

[20] C ANCUTI, C O ANCUTI, T HABER et al. Enhancing underwater images and videos by fusion, 81-88(2012).

[21] K R JOSHI, R S KAMATHE. Quantification of retinex in enhancement of weather degraded images, 1229-1233(2008).

[22] Mingming ZHANG. Research on underwaterimagecorrectiontechnology(2020).

[23] Caizhen ZHANG, Binlong KANG, Ying LI et al. Underwater image enhancement based on differential channel gain and improved retinex. Laser & Optoelectronics Progress, 58, 156-163(2021).

[24] J PEREZ, A C ATTANASIO, N NECHYPORENKO et al. A deep learning approach for underwater image enhancement, 183-192(2017).

[25] Y WANG, J ZHANG, Y CAO et al. A deep CNN method for underwater image enhancement, 1382-1386(2017).

[26] S ANWAR, C LI, F PORIKLI. Deep underwater image enhancement. arXiv e-prints(2018).

[27] X CAO, S RONG, Y LIU et al. NUICNet: Non-uniform illumination correction for underwater image using fully convolutional network. IEEE Access, 8, 109989-110002(2020).

[28] A DUDHANE, P HAMBARDE, P PATIL et al. Deep Underwater image restoration and beyond. IEEE Signal Processing Letters, 27, 675-679(2020).

[29] Y Q WANG, X N YU, D AN et al. Underwater image enhancement and marine snow removal for fishery based on integrated dual-channel neural network. Computers and Electronics in Agriculture, 186, 106182(2021).

[30] Y F HUANG, M Y LIU, F YUAN. Color correction and restoration based on multi-scale recursive network for underwater optical image. Signal Processing: Image Communication, 93, 116174(2021).

[31] I J GOODFELLOW, J POUGET-ABADIE, M MIRZA et al. Generative adversarial nets, 2672-2680(2014).

[32] J LI, K A SKINNER, R M EUSTICE et al. WaterGAN: unsupervised generative network to enable real-time color correction of monocular underwater images. IEEE Robotics and Automation Letters, 3, 387-394(2018).

[33] J ZHU, T PARK, P ISOLA et al. Unpaired image-to-image translation using cycle-consistent adversarial networks, 2242-2251(2017).

[34] C FABBRI, M JAHIDUL ISLAM, J SATTAR. Enhancing underwater imagery using generative adversarial networks. IEEE International Conference on Robotics and Automation, 7159-7165(2018).

[35] N LI, Z ZHENG, S ZHANG et al. The Synthesis of unpaired underwater images using a multistyle generative adversarial network. IEEE Access, 6, 54241-54257(2019).

[36] X ZONG, Z CHEN, D WANG. Local-CycleGAN: a general end-to-end network for visual enhancement in complex deep-water environment. Applied Intelligence, 51, 1947-1958(2021).

[37] C Y LI, A CAVALLARO. Cast-Gan: learning to remove color cast from underwater images, 1083-1087(2020).

[38] C LI, S ANWAR, F PORIKLI. Underwater scene prior inspired deep underwater image and video enhancement. Pattern Recognition, 98, 107038(2020).

[39] X YIN, X LIU, H LIU. FMSNet: Underwater image restoration by learning from a synthesized dataset, 421-432(2021).

[40] M J ISLAM, Y XIA, J SATTAR. Fast underwater image enhancement for improved visual perception. IEEE Robotics and Automation Letters, 5, 3227-3234(2020).

[41] Dexing WANG, Yue WANG, Hongchun YUAN. Underwater image enhancement based on Inception-Residual and generative adversarial network. Chinese Journal of Liquid Crystals and Displays, 36, 1474-1485(2021).

[42] K HE, J SUN, X TANG. Single image haze removal using dark channel prior. IEEE Transactions on Pattern Analysis and Machine Intelligence, 33, 2341-2353(2011).

[43] J Y CHIANG, Y C CHEN. Underwater image enhancement by wavelength compensation and dehazing. IEEE Transactions on Image Processing, 21, 1756-1769(2012).

[44] X ZHAO, T JIN, S QU. Deriving inherent optical properties from background color and underwater image enhancement. Ocean Engineering, 94, 163-172(2015).

[45] J P DREWS, E NASCIMENTO, F MORAES et al. Transmission estimation in underwater single images. IEEE International Conference on Computer Vision Workshops, 825-830(2013).

[46] H LU, Y LI, L ZHANG et al. Contrast enhancement for images in turbid water. Journal of the Optical Society of America A Optics Image Science & Vision, 32, 886-893(2015).

[47] L ZHENG, X Y DING, Y F WANG et al. GUDCP: generalization of underwater dark channel prior for underwater image restoration. IEEE Transactions on Circuits and Systems for Video Technology, 1-5(2021).

[48] A GALDRAN, D PARDO, PICÓNA et al. Automatic red-channel underwater image restoration. Journal of Visual Communication & Image Representation, 26, 132-145(2015).

[49] B N CARLEVARIS, A MOHAN, R M EUSTICE. Initial results in underwater single image dehazing, 1-8(2010).

[50] X ZHAO, T JIN, S QU. Deriving inherent optical properties from background color and underwater image enhancement. Ocean Engineering, 94, 163-172(2015).

[51] Y T PENG, X ZHAO, P C COSMAN. Single underwater image enhancement using depth estimation based on blurriness. IEEE International Conference on Image Processing, 4952-4956(2015).

[52] Y T PENG, P C COSMAN. Underwater image restoration based on image blurriness and light absorption. IEEE Trans Image Process, 26, 1579-1594(2017).

[53] Y WANG, J CAO, S RIZVI et al. Underwater image restoration based on adaptive color compensation and dual transmission estimation. IEEE Access, 8, 207834-207843(2020).

[54] K WANG, Y HU, J CHEN et al. Underwater image restoration based on a parallel convolutional neural network. Remote Sensing, 11, 1591(2019).

[55] X DING, Y WANG, J ZHANG et al. Underwater image dehaze using scene depth estimation with adaptive color correction, 1-5(2017).

[56] K CAO, Y T PENG, P C COSMAN. Underwater image restoration using deep networks to estimate background light and scene depth. IEEE Southwest Symposium on Image Analysis and Interpretation, 1-4(2018).

[57] P W PAN, F YUAN, E CHENG. De-scattering and edge-enhancement algorithms for underwater image restoration. Frontiers of Information Technology & Electronic Engineering, 20, 862-871(2019).

[58] Y F LIN, L Q SHEN, Z Y WANG et al. Attenuation coefficient guided two-stage network for underwater image restoration. IEEE Signal Processing Letters, 199-203(2021).

[59] W V BARBOSA, H AMARAL, T L ROCHA et al. Visual-quality-driven learning for underwater vision enhancement. IEEE International Conference on Image Processing, 3933-3937(2018).

[60] T UEDA, K YAMADA, Y TANAKA. Underwater image synthesis from rgb-d images and its application to deep underwater image restoration. IEEE International Conference on Image Processing, 2115-2119(2019).

[61] Pingli HAN. Underwater targets detection based on polarization imaging(2018).

[62] Fei LIU, Shaojie SUN, Pingli HAN et al. Development of underwater polarization imaging technology. Laser & Optoelectronics Progress, 58, 9-26(2021).

[63] Jinge GUAN, Jingping ZHU, Heng TIAN et al. Real-time polarization difference underwater imaging based on Stokes vector. Acta Physica Sinica, 64, 141-147(2015).

[64] J WANG, M WAN, G GU et al. Periodic integration-based polarization differential imaging for underwater image restoration. Optics and Lasers in Engineering, 149, 106785(2022).

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

[66] B HUANG, T LIU, H HU et al. Underwater image recovery considering polarization effects of objects. Optics Express, 24, 9826-9838(2016).

[67] Y GU, C CARRIZO, A A GILERSON et al. Polarimetric imaging and retrieval of target polarization characteristics in underwater environment. Applied Optics, 55, 626-637(2016).

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

[69] Fei FENG, Guojun WU, Yafeng WU et al. Algorithm for underwater polarization imaging based on global estimation. Acta Optica Sinica, 40, 75-83(2020).

[70] Y WEI, P L HAN, F LIU et al. Polarization descattering imaging: a solution for nonuniform polarization characteristics of a target surface. Chinese Optics Letters, 19, 111101(2021).

[71] X LI, H LI, Y LIN et al. Learning-based denoising for polarimetric images. Optics Express, 28, 16309-16321(2020).

[72] H HU, Y ZHANG, LIX et al. Polarimetric underwater image recovery via deep learning. Optics and Lasers in Engineering, 133, 106152(2020).

[73] R ZHANG, X GUI, H CHENG et al. Underwater image recovery utilizing polarimetric imaging based on neural networks. Applied Optics, 60, 8419-8425(2021).

[74] Wenbing ZENG. Research on underwater long-distance ghost imaging technology(2018).

[75] Rui XU. Design and implementation of underwater laser imaging system based on ghost imaging(2020).

[76] R S BENNINK, S J BENLEY, R W BPYD. “Two-photon”coincidence imaging with a classical source. Physical Review Letters, 89, 113601(2002).

[77] J H SHAPIRO. Computational ghost imaging. Physical Review A, 78, 061802(2008).

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

[79] F FERRI, D MAGATTI, L A LUGIATO et al. Differential ghost imaging. Physical Review Letters, 104, 253603(2010).

[80] Y ZHANG, W LI, Y YU et al. Ghost imaging enhancement for detections of the low-transmittance objects. International Journal of Advanced Robotic Systems, 17, 1-7(2020).

[81] O KATZ, Y BROMBERG, Y SILBERBERG. Compressive ghost imaging. Applied Physics Letters, 95, 739(2009).

[82] Y ZHANG, W LI, H WU et al. High-visibility underwater ghost imaging in low illumination. Optics Communications, 441, 45-48(2019).

[83] T WANG, M CHEN, H WU et al. Underwater compressive computational ghost imaging with wavelet enhancement. Applied Optics, 60, 6950-6957(2021).

[84] X YANG, Z Y YU, L XU et al. Underwater ghost imaging based on generative adversarial networks with high imaging quality. Optics Express, 29, 28388-28405(2021).

[85] M LYU, W WANG, H WANG et al. Deep-learning-based ghost imaging. Scientific Reports, 7, 17865(2017).

[86] F WANG, H WANG, H WANG et al. Learning from simulation: An end-to-end deep-learning approach for computational ghost imaging. Optics Express, 27, 25560-25572(2019).

[87] F Q LI, M ZHAO, Z TIAN et al. Compressive ghost imaging through scattering media with deep learning. Optics Express, 28, 17395-17408(2020).

[88] H WU, R WANG, G ZHAO et al. Sub-Nyquist computational ghost imaging with deep learning. Optics Express, 28, 3846-3853(2020).

[89] He WEI. Underwater spectral imaging with filter wheel(2018).

[90] LÜ Qunbo. Data processing of fourier transform imaging spectroscopy(2007).

[91] G JOHNSEN, Z VOLENT, H DIERSSEN et al. Underwater hyperspectral imagery to create biogeochemical maps of seafloor properties, 508-535(2013).

[92] Jiamin SUN, Huihui SONG. Hyperspectral and multispectral image fusion based on discrete wavelet transform and generative adversarial networks. Radio Engineer, 1-9. http://kns.cnki.net/kcms/detail/13.1097.tn.20211119.1615.018.html

[93] G JOHNSEN, Z VOLENT, E SAKSHAUG et al. Remote sensing in the barents sea. in ecosystem barents sea, 139-166(2009).

[94] G JOHNSEN, M LUDVIGSEN, A SORENSEN et al. The use of underwater hyperspectral imaging deployed on remotely operated vehicles - methods and applications. IFAC Papers on Line, 49, 476-481(2016).

[95] A CHENNU, P FÄRBER, G DE'ATH et al. A Diver-Operated hyperspectral imaging and topographic surveying system for automated mapping of benthic habitats. Scientific Reports, 7, 7122(2017).

[96] A CHENNU, P FÄRBER, N VOLKENBORN et al. Hyperspectral imaging of the microscale distribution and dynamics of microphytobenthos in intertidal sediments. Limnology and Oceanography:Methods, 11, 511-528(2013).

[97] F FOGLINI, V GRANDE, F MARCHESE et al. Application of hyperspectral imaging to underwater habitat mapping, southern adriatic sea. Sensors, 19, 2261(2019).

[98] H B LIU, J STICKLUS, K KÖSER et al. TuLUMIS - Atunable LED-based underwater multispectral imaging system. Optics Express, 26, 7811-7828(2018).

[99] Yilu GUO. Research of underwater spectral image restoration methods for staring spectral imaging system(2019).

[100] X FU, X SHANG, X SUN et al. Underwater hyperspectral target detection with band selection. Remote Sensing, 12, 1056(2020).

[101] Haokui ZHANG, Ying LI, Yenan JIANG. Deep learning for hyperspectral imagery classification: the state of the art and prospects. Acta Automatica Sinica, 44, 961-977(2018).

[102] Chenning TAO. Research on spectral imaging systems and reconstruction algorithms based on compressive sensing(2021).

[103] D SARA, A K MANDAVA, A KUMAR et al. Hyperspectral and multispectral image fusion techniques for high resolution applications: a review. Earth Science Informatics, 14, 1685-1705(2021).

[104] R DIAN, S LI, B SUN et al. Recent advances and new guidelines on hyperspectral and multispectral image fusion. Information Fusion, 69, 40-51(2021).

[105] Y ZHANG, Y GAO, Y LIU et al. Hyperspectral and multispectral image fusion based on constrained CNMF unmixing. 2015 7th Workshop on Hyperspectral Image and Signal Processing: Evolution in Remote Sensing (WHISPERS), 1-4(2015).

[106] N YOKAYA, T YAIRI, A IWASAKI. Coupled nonnegative matrix factorization unmixing for hyperspectral and multispectral data fusion. IEEE Transactions on Geoscience & Remote Sensing, 50, 528-537(2012).

[107] J GU, Z WANG, J KUEN et al. Recent advances in convolutional neural networks. Pattern Recognition, 77, 354-377(2018).

[108] F PALSSON, J R SVEINSSON, M O ULFARSSON. Multispectral and hyperspectral image fusion using a 3-d-convolutional neural network. IEEE Geoscience and Remote Sensing Letters, 14, 639-643(2017).

[109] W YANG, X ZHANG, Y TIAN et al. Deep learning for single image super-resolution: a brief review. IEEE Transactions on Multimedia, 21, 3106-3121(2019).

[110] J GAO, J LI, M JIANG. Hyperspectral and multispectral image fusion by deep neural network in a self-supervised manner. Remote Sensing, 13, 3226(2021).

[111] D L DONOHO. Compressedsensing. IEEE Transactions on Information Theory, 52, 1289-1306(2006).

[112] Rong ZENG. Research on key technology of compress sensing under water optical imaging system(2014).

[113] Ziran WEI, Wei YANG, Jianlin ZHANG et al. Super-resolution imaging optimization of single pixel camera based on deep learning. Semiconductor Optoelectronics, 42, 412-417(2021).

[114] M F DUARTE, M A DAVENPORT, D TAKBAR et al. Single-pixel imaging via compressive sampling. IEEE Signal Processing Magazine, 25, 83-91(2008).

[115] D TAKHAR, J N LASKA, M B WAKIN et al. A new compressive imaging camera architecture using optical-domain compression, 6005, 43-52(2006).

[116] G M GIBSON, S D JOHNSON, M J PADGETT et al. Single-pixel imaging 12 years on: a review. Optics Express, 28, 28190-28208(2020).

[117] Wenkai YU, Feiyao TANG, Shuofei WANG et al. Dynamic single-pixel imaging. Laser & Optoelectronics Progress, 58, 181-192(2021).

[118] Zibang ZHANG, Tianao LU, Junzheng PENG et al. Fourier single-pixel imaging techniques and applications. Infrared and Laser Engineering, 48, 22-40(2019).

[119] Z ZHANG, X WANG, G ZHENG et al. Hadamard single-pixel imaging versus fourier single-pixel imaging. Optics Express, 25, 19619-19639(2017).

[120] B LIU, Z YANG, X LIU et al. Coloured computational imaging with single-pixel detectors based on a 2d discrete cosine transform. Journal of Modern Optics, 64, 259-264(2017).

[121] F ROUSSET, N DUCROS, A FARINA et al. Adaptive basis scan by wavelet prediction for single-pixel imaging. IEEE Transactions on Computational Imaging, 3, 36-46(2017).

[122] M SUN, M P EDGAR, D B PHILLIPS et al. Improving the signal-to-noise ratio of single-pixel imaging using digital microscanning. Optics Express, 24, 10476-10485(2016).

[123] Z ZHANG, X MA, J ZHONG. Single-pixel imaging by means of fourier spectrum acquisition. Nature Communications, 6, 6225(2014).

[124] LÜ Pei. Research of underwater imaging technology and image compression technology based on compressive sensing theory(2012).

[125] Q CHEN, CHAMOLI , S K , P YIN et al. Active mode single pixel imaging in the highly turbid water environment using compressive sensing. IEEE Access, 7, 159390-159401(2019).

[126] X YANG, Y LIU, X MOU et al. Imaging in turbid water based on a hadamard single-pixel imaging system. Optics Express, 29, 12010-12023(2021).

[127] Z ZHANG, S LIU, J PENG et al. Simultaneous spatial, spectral, and 3d compressive imaging via efficient fourier single-pixel measurements. Optica, 5, 315-319(2018).

[128] Z ZHANG, X WANG, G ZHENG et al. Fast fourier single-pixel imaging via binary illumination. Scientific Reports, 7, 12029(2017).

[129] X YANG, P JIANG, L WU et al. Underwater fourier single pixel imaging based on water degradation function compensation method. Infrared and Laser Engineering, 49, 244-255(2020).

[130] Y HU, Z CHENG, FAN , X et al. Optimizing the quality of fourier sing-pixel imaging via generative adversarial network. Optik, 227, 166060(2021).

[131] S RIZVI, J CAO, K ZHANG et al. Improving imaging quality of real-time fourier single-pixel imaging via deep learning. Sensors, 19, 4190(2019).

[132] C F HIGHAM, R MURRAY-SMITH, M J PADGETT et al. Deep learning for real-time single-pixel video. Scientific Reports, 8, 2369(2018).

[133] M LI, A MATHAI, S L H LAU et al. Underwater object detection and reconstruction based on active single-pixel imaging and super-resolution convolutional neural network. Sensors, 21, 313(2021).

[134] K UMEHARA, J OTA, T ISHIDA. Super-resolution imaging of mammograms based on the super-resolution convolutional neural network. Open Journal of Medical Imaging, 7, 180-195(2017).

[135] Wei HUANG, Shuming JIAO, Changyan XIAO. Image processing algorithms related to single-pixel imaging: a review. Laser & Optoelectronics Progress, 58, 267-284(2021).

[136] Huayong YANG, Yonghui LIANG. Present situation and prospect of searching underwater objects by airborne blue-green laser system. Laser Technology & Applications, 12, 6-10(2003).

[137] Tianci XU. System design and research on laser imaging for underwater target(2013).

[138] Weiqi JIN, Xia WANG, Fengmei CAO et al. Review of underwater opto-electrical imaging technology and equipment (II). Infrared Technology, 33, 125-132(2011).

[139] K D MOORE, J S JAFFE, B L OCHOA. Development of a new underwater bathymetric laser imaging system: L-bath. Journal of Atmospheric and Oceanic Technology, 17, 1106-1117(2000).

[140] Jianfeng SUN, Jian GAO, Jingsong WEI et al. Research development of underwater detection imaging based on streak tube imaging lidar. Infrared and Laser Engineering, 39, 811-814(2010).

[141] G R FOURNIER, D BONNIER, J L FORAND et al. Range-gated underwater laser imaging system. Optical Engineering, 32, 2185-2190P(1993).

[142] Zhengyu ZHANG, Shouhuan ZHOU. Analys of key technology and the applications of underwater target detection by LASER. Journal of Xidian University(Natural Science), 28, 797-781(2001).

[143] Xuguang YAN, Fuyuan PENG, Guohua XU et al. Analysis of temporal and frequency characteristic of fore-scattered laser in ocean channel. Laser Technology, 29, 266-269(2005).

[144] Y KITAJIMA, D IWAI, K SATO. Simultaneous projection and positioning of laser projector pixels. IEEE Transactions on Visualization and Computer Graphics, 23, 2419-2429(2017).

[145] H WU, M ZHAO, W XU. Underwater De-scattering imaging by laser field synchronous scanning. Optics and Lasers in Engineering, 126, 105871(2020).

[146] Y YANG, B ZHENG, L Y KAN et al. 3D color reconstruction based on underwater RGB laser line scanning system. Optik, 125, 6074-6077(2014).

[147] G ASHER, C R BRIAN, S L ROBERT et al. Flash lidar based on multiple-slit streak tube imaging lidar(2002).

[148] Wenjie HAN, Guangyan DONG, Fengchao PENG et al. Research of high resolution imaging lidar for target under water. Optoelectronic Technology, 40, 1-5+18(2020).

[149] F K KNIGHT, D I KLICK, D P RYAN-HOWARD et al. Three-dimensional imaging using a single laser pulse, 1103, 174-189(1989).

[150] J N ANDREW. Automated processing for streak tube imaging lidar data, 119-129(2003).

[151] W M JOHN. High-resolution 3D underwater imaging, 10-19(1999).

[152] J W MCLEAN, J T MURRAY. Streak-tube lidar allows 3-D ocean surveillance. Laser Focus World, 34, 171-176(1998).

[153] S ROGER, B HOWARD. Staring underwater laser radar (SULAR) 3D imaging, 57-64(2001).

[154] G ASHER, W CHRIS, B DSHANNON et al. FLASH lidar data collections in terrestrial and ocean environments, 5086, 27-38(2003).

[155] V T HOLMES, A W JAMES, A M KAREN et al. Lidar signatures of very shallow water (VSW) and surf zone (SZ) mines, 5089, 285-295(2003).

[156] J GAO, J SUN, Q WANG. Experiments of ocean surface waves and underwater target detection imaging using a slit Streak Tube Imaging Lidar. Optik, 125, 5199-5201(2014).

[157] Guoquan XU, Guangying LI, Jianwei WAN et al. Underwater imaging system of pulse modulated lidar. Infrared and Laser Engineering, 1-9. http://kns.cnki.net/kcms/detail/12.1261.TN.20210621.1757.010.html

[158] G LI, Q ZHOU, G XU et al. Lidar-radar for underwater target detection using a modulated sub-nanosecond Q-switched laser. Optics & Laser Technology, 142, 107234(2021).

[159] W LIU, Q LI, G HAO et al. Experimental study on underwater range-gated imaging system pulse and gate control coordination strategy(2018).

[160] G R FOURNIER, D. BONNIER, L FORAND et al. LUCIE ROV mounted laser imaging system, 1750, 443-452(1992).

[161] G R FOURNIER, D BONNIER, J L FORAND et al. Range-gated underwater laser imaging system. Optical Engineering, 32, 2185-2190(1993).

[162] A WEIDEMANN, G R FOURNIER, L FORAND et al. In harbor underwater threat detection identification using active imaging, 5780, 59-70(2005).

[163] G R FOURNIER, J L FORAND, P MATHIEU et al. Range-gated active underwater imaging: evolution, performance and perspectives, 1-29(2008).

[164] B A SWARTZ. Laser range gate underwater imaging advances, 2, 722-727(1994).

[165] E A MCLEAN, H R BURRIS. Short-pulse range-gated optical imaging in turbid water. Applied Optics, 34, 4343-4351(1995).

[166] C S TAN, A SLUZEK, T Y JIANG et al. Range gated imaging system for underwater robotic vehicle, 1-6(2006).

[168] W JIN, F CAO, X WANG et al. Rang-gated underwater laser imaging system based on intensified gate imaging technology, 6621(2007).

[169] Yanjun CHANG, Fuyuan PENG. Laser underwaterimagingtechniqueandexperiment. Research and Explorationin Laboratory, 28, 19-21(2009).

[170] Dong LI, Huajun YANG, Qiuzhen ZHENG et al. Application of range-gated technology in the three-dimensional imaging laser radar. Infrared and Laser Engineering, 41, 85-88(2012).

[171] Ziheng HUANG. Research on underwater target 3-D imaging method based on range-gated laser imaging technology(2016).

[172] P RISHOLM, J THORSTENSEN, J T THIELEMANN et al. Real-time super-resolved 3D in turbid water using a fast range-gated CMOS camera. Applied Optics, 57, 3927-3937(2018).

[173] J BUSCK. Underwater 3-D optical imaging with a gated viewing laser radar. Optical Engineering, 44, 116001(2005).

[174] Qingbo ZHANG, Xiaohui ZHANG, Hongwei HAN. Backscattered light repairing method for underwater laser image based on improved generative adversarial network. Laser Technology & Applications, 56, 114-122(2019).

[175] L ZHOU, Y XIAO, W CHEN. Imaging through turbid media with vague concentrations based on cosine similarity and convolutional neural network. IEEE Photonics Journal, 11, 1-15(2019).

[176] D W ILLIG, K X KOCAN, L J MULLEN. Machine learning applied to the underwater radar-encoded laser system, 1-6(2020).

[177] Qingyu YUAN. Research on underwater three-dimensional imaging and image processing of streak tube imaging lidar(2018).

[178] J DI, Y YU, Z WANG et al. Quantitative measurement of thermal lensing in diode-side-pumped Nd:YAG laser by use of digital holographic interferometry. Optics Express, 24, 28185-28193(2016).

[179] J DI, J ZHAO, H JIANG et al. High resolution digital holographic microscopy with a wide field of view based on a synthetic aperture technique and use of linear CCD scanning. Applied Optics, 47, 5654-5659(2008).

[180] W SUN, J ZHAO, J DI et al. Real-time visualization of Karman vortex street in water flow field by using digital holography. Optics Express, 17, 20342-20348(2009).

[181] Y ZHANG, J ZHAO, J DI et al. Real-time monitoring of the solution concentration variation during the crystallization process of protein-lysozyme by using digital holographic interferometry. Optics Express, 20, 18415-18421(2012).

[182] J ZHAO, H JIANG, J DI. Recording and reconstruction of a color holographic image by using digital lensless Fourier transform holography. Optics Express, 16, 2514-2519(2008).

[183] C KNOX. Holographic microscopy as a technique for recording dynamic microscopic subjects. Science, 153, 989-990(1966).

[184] J R BEERS, C KNOX, J D H STRICKLAND. A permanent record of plankton samples using holography. Limnology and Oceanography, 15, 967-970(1970).

[185] C KNOX, R E BROOKS, D GABOR. Holographic motion picture microscopy. Proceedings of the Royal Society of London, Series B: Biological Sciences, 174, 115-121(1969).

[186] J KATZ, P L DONAGHAY, J ZHANG et al. Submersible holocamera for detection of particle characteristics and motions in the ocean. Deep Sea Research Part I: Oceanographic Research Papers, 46, 1455-1481(1999).

[187] B O ROBERT, A Z ALEX. In-line digital holographic sensor for monitoring and characterizing marine particulates. Optical Engineering, 39, 2187-2197(2000).

[188] S K JERICHO, S J GARCIA, W XU et al. Submersible digital in-line holographic microscope. Review of Scientific Instruments, 77, 043706(2006).

[189] E MALKIEL, J N ABRAS, J KATZ. Automated scanning and measurements of particle distributions within a holographic reconstructed volume. Measurement Science and Technology, 15, 601-612(2004).

[190] A R NAYAK, E MALKIEL, M N MCFARLAND et al. A Review of holography in the aquatic sciences: In situ characterization of particles, plankton, and small scale biophysical interactions. Frontiers in Marine Science, 7(2021).

[191] G W GRAHAM, W A M NIMMO SMITH. The application of holography to the analysis of size and settling velocity of suspended cohesive sediments. Limnology and Oceanography: Methods, 8, 1-15(2010).

[192] J CROSS, W A M NIMMO SMITH, R TORRES et al. Biological controls on resuspension and the relationship between particle size and the Kolmogorov length scale in a shallow coastal sea. Marine Geology, 343, 29-38(2013).

[193] Y WANG, W ZHANG, X YU. Measurement of suspended particle and plankton with a digital in-line holographic system, 1-4(2016).

[194] A R NAYAK, M N MCFARLAND, J M SULLIVAN et al. Evidence for ubiquitous preferential particle orientation in representative oceanic shear flows. Limnology and Oceanography, 63, 122-143(2018).

[195] V DYOMIN, A DAVYDOVA, S DAVYDOV et al. Hydrobiological probe for the in situ study and monitoring of zooplankton, 1-6(2019).

[196] T S MOORE, C B MOUW, J M SULLIVAN et al. Bio-optical properties of cyanobacteria blooms in Western Lake Erie. Frontiers in Marine Science, 4(2017).

[197] T S MOORE, J H CHURNSIDE, J M SULLIVAN et al. Vertical distributions of blooming cyanobacteria populations in a freshwater lake from LIDAR observations. Remote Sensing of Environment, 225, 347-367(2019).

[198] K MALLERY, D CANELON, J HONG et al. Design and experiments with a robot-driven underwater holographic microscope for low-cost in situ particle measurements. Journal of Intelligent & Robotic Systems, 102, 32(2021).

[199] V DYOMIN, A DAVYDOVA, I POLOVTSEV et al. Underwater holographic sensor for plankton studies in situ including accompanying measurements. Sensors, 21, 4863(2021).

[200] G ZHANG, T GUAN, Z SHEN et al. Fast phase retrieval in off-axis digital holographic microscopy through deep learning. Optics Express, 26, 19388-19405(2018).

[201] W XIAO, Q WANG, F PAN et al. Adaptive frequency filtering based on convolutional neural networks in off-axis digital holographic microscopy. Biomedical Optics Express, 10, 1613-1626(2019).

[202] Zhang MENG, Hao DING, Shouping NIE et al. Application of deep learning in digital holographic microscopy. Laser Technology & Applications, 58, 1811006(2021).

[203] A SINHA, J LEE, S LI et al. Lensless computational imaging through deep learning. Optica, 4, 1117-1125(2017).

[204] H WANG, M LYU, G SITU. eHoloNet: a learning-based end-to-end approach for in-line digital holographic reconstruction. Optics Express, 26, 22603-22614(2018).

[205] K WANG, J DOU, Q KEMAO et al. Y-Net: a one-to-two deep learning framework for digital holographic reconstruction. Optics Letters, 44, 4765-4768(2019).

[206] K WANG, Q KEMAO, J DI et al. Y4-Net: a deep learning solution to one-shot dual-wavelength digital holographic reconstruction. Optics Letters, 45, 4220-4223(2020).

[207] S SHAO, K MALLERY, S S KUMAR et al. Machine learning holography for 3D particle field imaging. Optics Express, 28, 2987-2999(2020).

[208] T SHIMOBABA, T TAKAHASHI, Y YAMAMOTO et al. Digital holographic particle volume reconstruction using a deep neural network. Applied Optics, 58, 1900-1906(2019).

[209] K MALLERY, J HONG. Regularized inverse holographic volume reconstruction for 3D particle tracking. Optics Express, 27, 18069-18084(2019).

[210] Z SHI, K WANG, L CAO et al. Study on holographic image recognition technology of zooplankton. DEStech Transactions on Computer Science and Engineering(2019).

[211] B GUO, L NYMAN, A R NAYAK et al. Automated plankton classification from holographic imagery with deep convolutional neural networks. Limnology and Oceanography: Methods, 19, 21-36(2021).

[212] E COTTER, E FISCHELL, A LAVERY. Computationally efficient processing of in situ underwater digital holograms. Limnology and Oceanography: Methods, 19, 476-487(2021).

[213] P J HUBER. Robust estimation of a location parameter(1964).