[1] Zhang Z Q, Zhang Y. Light field imaging with micro lens array[J]. Journal of Capital Normal University (Natural Science Edition), 37, 15-19(2016).

[2] Xu Y K. Influence of atmosphere scattering on correlated imaging[D], 39-44(2014).

[3] Wang Q Z, Liang X, Wang L et al. Fourier spatial filter acts as a temporal gate for light propagating through a turbid medium[J]. Optics Letters, 20, 1498-1500(1995).

[4] Mujumdar S, Ramachandran H. Imaging through turbid media using polarization modulation:dependence on scattering anisotropy[J]. Optics Communications, 241, 1-9(2004).

[5] Wang L, Ho P P, Liang X et al. Kerr-Fourier imaging of hidden objects in thick turbid media[J]. Optics Letters, 18, 241(1993).

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

[7] Zhu Y C, Shi J H, Yang Y et al. Polarization difference ghost imaging[J]. Applied Optics, 54, 1279-1284(2015).

[8] Li M F, Mo X F, Zhang A N. The key technics in quantum imaging and its researching status[J]. Navigation and Control, 15, 1-9, 16(2016).

[9] Zhao Y, Li G L, Yang Z H. Development of quantum correlation imaging technology[J]. Aero Weaponry, 3-10(2017).

[10] Brown R H, Twiss R Q. A test of a new type of stellar interferometer on Sirius[J]. Nature, 178, 1046-1048(1956).

[11] Brown R H, Twiss R Q. Correlation between photons in two coherent beams of light[J]. Journal of Astrophysics and Astronomy, 15, 13-19(1994).

[12] Klyshko D N. Two-photon light: influence of filtration and a new possible EPR experiment[J]. Physics Letters A, 128, 133-137(1988).

[13] Shih Y H, Sergienko A V, Rubin M H et al. Two-photon entanglement in type-II parametric down-conversion[J]. Physical Review A, Atomic, Molecular, and Optical Physics, 50, 23-28(1994).

[14] Pittman T B, Shih Y H, Strekalov D V et al. Optical imaging by means of two-photon quantum entanglement[J]. Physical Review A, Atomic, Molecular, and Optical Physics, 52, R3429-R3432(1995).

[15] Bennink R S, Bentley S J, Boyd R W. “Two-photon” coincidence imaging with a classical source[J]. Physical Review Letters, 89, 113601(2002).

[16] Zhang D, Zhai Y H, Wu L A et al. Correlated two-photon imaging with true thermal light[J]. Optics Letters, 30, 2354-2356(2005).

[17] Shapiro J H. Computational ghost imaging[C]. //International Quantum Electronics Conference 2009, May 31-June 5, 2009, Baltimore, Maryland, IThK7(2009).

[18] Bromberg Y, Katz O, Silberberg Y. Ghost imaging with a single detector[J]. Physical Review A, 79, 053840(2009).

[19] Chen H, Peng T, Shih Y. 100% correlation of chaotic thermal light[J]. Physical Review A, 88, 023808(2013).

[20] Wang W, Wang Y P, Li J H et al. Iterative ghost imaging[J]. Optics Letters, 39, 5150-5153(2014).

[21] Edgar M P, Gibson G M, Bowman R W et al. Simultaneous real-time visible and infrared video with single-pixel detectors[J]. Scientific Reports, 5, 10669(2015).

[22] Sun M J, Edgar M P, Gibson G M et al. Single-pixel three-dimensional imaging with time-based depth resolution[J]. Nature Communications, 7, 12010(2016).

[23] Hardy N D, Shapiro J H. Computational ghost imaging versus imaging laser radar for three-dimensional imaging[J]. Physical Review A, 87, 023820(2013).

[24] Yin L F, Wu G H, Yin P Q. Real-time displaying ghost imaging scheme: CN110132324A[P](2019).

[25] Li X H, Deng C J, Chen M L et al. Ghost imaging for an axially moving target with an unknown constant speed[J]. Photonics Research, 3, 153-157(2015).

[26] Song Z Y, Yang Z H, Yu Y J et al. Tracking compensation in computational ghost imaging of the moving targets[J]. Optical Technique, 45, 343-347(2019).

[27] Magaña-Loaiza O S, Howland G A, Malik M et al. Compressive object tracking using entangled photons[J]. Applied Physics Letters, 102, 231104(2013).

[28] Shi D F, Yin K X, Huang J et al. Fast tracking of moving objects using single-pixel imaging[J]. Optics Communications, 440, 155-162(2019).

[29] Gong W L, Han S S. Correlated imaging in scattering media[J]. Optics Letters, 36, 394-396(2011).

[30] Chen M L, Li E R, Gong W L et al. Ghost imaging lidar via sparsity constraints in real atmosphere[J]. Optics and Photonics Journal, 3, 83-85(2013).

[31] Zhang Y Z. Experimental study of correlated imaging and algorithm design[D], 34-40(2014).

[32] Zhou C, Liu B, Huang H Y et al. Effect of scattering medium on multi-wavelength color object correlated imaging[J]. Laser & Optoelectronics Progress, 53, 101102(2016).

[33] Jin H Q, Shi J H, Peng J Y et al. Looking around corners and through turbid media with projector[J]. Acta Optica Sinica, 34, 0511006(2014).

[34] Ma Y Q, Zhang Z J, Wu C Q. Experiment study on ghost imaging in strong absorption and weak scattering media[J]. Optical Instruments, 42, 58-62(2020).

[35] Hu Y D, Cheng Z D, Liang Z Y et al. Experimental study on laser computational ghost imaging through smoke media[J]. Chinese Journal of Lasers, 48, 0401020(2021).

[36] Zhong S C, Li Z R, Wang R B. Forward-scattering effect on underwater laser imaging[J]. High Power Laser and Particle Beams, 24, 61-64(2012).

[37] Zhao M J. Research on underwater polarization-based ghost imaging[D], 33-39(2019).

[38] Zhao M, Wang Y, Tian Z M et al. Method of push-broom underwater ghost imaging computation[J]. Laser & Optoelectronics Progress, 56, 161101(2019).

[39] Yin M Q. Underwater ghost imaging of amplitude and phase objects[D], 26-36(2020).

[40] Bina M, Magatti D, Molteni M et al. Backscattering differential ghost imaging in turbid media[J]. Physical Review Letters, 110, 083901(2013).

[41] Durán V, Soldevia F, Irles E et al. Imaging at depth in tissue with a single-pixel camera[EB/OL]. (2014-11-11)[2021-03-02]. http://arxiv.org/abs/1411.2731

[42] Liu B L, Yang Z H, Qu S F et al. Influence of turbid media at different locations in computational ghost imaging[J]. Acta Optica Sinica, 36, 1026017(2016).

[43] Li W, Yang Z H, Chen X et al. Research on super-resolution anti-interference detection system based on active and passive quantum correlation imaging[J]. Navigation and Control, 19, 34-39, 96(2020).

[44] Yang Z H, Li W. Experimental study on the influence of scattering media on intensity correlation imaging[J]. Physics and Engineering, 30, 79-83, 88(2020).

[45] Yang Z, Zhao L J, Zhao X L et al. Lensless ghost imaging through the strongly scattering medium[J]. Chinese Physics B, 25, 024202(2016).

[46] Gao Z Q, Cheng X M, Chen K et al. Computational ghost imaging in scattering media using simulation-based deep learning[J]. IEEE Photonics Journal, 12, 1-15(2020).

[47] Zhuang J Y, Chen Q, He W J et al. Imaging through dynamic scattering media with compressed sensing[J]. Acta Physica Sinica, 65, 040501(2016).

[48] Hu Y D, Cheng Z D, Liang Z Y et al. Computational ghost imaging using a dynamic scattering medium by the point-by-point compensation method[J]. Laser & Optoelectronics Progress, 57, 201106(2020).

[49] Gao Z J, Yin J H, Bai Y F et al. Imaging quality improvement of ghost imaging in scattering medium based on Hadamard modulated light field[J]. Applied Optics, 59, 8472-8477(2020).

[50] Li F Q, Zhao M, Tian Z M et al. Compressive ghost imaging through scattering media with deep learning[J]. Optics Express, 28, 17395-17408(2020).