[1] Jingyao Wu, Xiuqin Su, Jingjing Tan, . Study of theory for transient imaging of hidden object using single-photon array detector. Infrared and Laser Engineering, 47, S122002(2018).
[2] A Mccarthy, N J Krichel, N R Gemmell, et al. Kilometer-range, high resolution depth imaging via 1560 nm wavelength single-photon detection. Optics Express, 21, 8904-8915(2013).
[3] Z Bao, Y Liang, Z Wang, et al. Laser ranging at few-photon level by photon-number-resolving detection. Applied Optics, 53, 3908-3912(2014).
[4] A Maccarone, A Mccarthy, X Ren, et al. Underwater depth imaging using time-correlated single-photon counting. Optics Express, 23, 33911-33926(2015).
[5] Y Liang, J Huang, M Ren, et al. 1550-nm time-of-flight ranging system employing laser with multiple repetition rates for reducing the range ambiguity. Optics Express, 22, 4662-4670(2014).
[6] M Ren, X Gu, Y Liang, et al. Laser ranging at 1550 nm with 1-GHz sine-wave gated InGaAs/InP APD single-photon detector. Optics Express, 19, 13497-13502(2011).
[7] R Cao, J Xu, C Yang, et al. High-resolution non-line-of-sight imaging employing active focusing. Nat Photonics, 16, 462-468(2022).
[8] Z Li, X Huang, Y Cao, et al. Single-photon computational 3D imaging at 45 km. Photonics Research, 8, 1532-1540(2020).
[9] Qiaoying He, Linhai Huang, Naiting Gu. 3D single photon imaging technology research based on MPPC array. Infrared and Laser Engineering, 51, 20210989(2022).
[10] Chihao Liu, Yunfei Chen, Naiting Gu, . Simulation and accuracy analysis of single photon ranging system. Infrared and Laser Engineering, 43, 382-387(2014).
[11] A M Pawlikowska, A Halimi, R A Lamb, et al. Single-photon three-dimensional imaging at up to 10 kilometers range. Optics Express, 25, 11919-11931(2017).
[12] Z Li, J Ye, X Huang, et al. Single-photon imaging over 200 km. Optica, 8, 344-349(2021).
[13] D Shin, F Xu, D Venkatraman, et al. Photon-effificient imaging with a single-photon camera. Nat Communication, 7, 12046-12046(2016).
[14] Z Li, E Wu, C Pang, et al. Multi-beam single-photon-counting three-dimensional imaging lidar. Optics Express, 25, 10189-10195(2017).
[15] H Araki, S Tazawa, H Noda, et al. Lunar global shape and polar topography derived from Kaguya-LALT laser altimetry. Science, 323, 897-900(2009).
[16] Harding D, Dabney P, Abshire J, et al. The slope imaging multipolarization photoncounting lidar: an advanced technology airbne laser altimeter [R]. NASA Earth Science Technology Fum, 2010: 253–256.
[17] John D. Photon counting lidars f airbne spacebne topographic mapping [C]Applications of Lasers f Sensing Free Space Communications, 2010.
[18] D John. Scanning, multiple, single photon lidars for rapid, large scale, high resolution, topographic and bathymetric mapping. Remote Sensing, 8, 958(2016).
[19] J Rapp, Y Ma, V K Goyal, et al. High-flux single-photon lidar. Optica, 8, 30-39(2021).
[20] D L Snyder. Random point processes. Journal of the Royal Statistical Society, 139, 990(1975).
[21] P Huang, W He, G Gu, et al. Depth imaging denoising of photon-counting lidar. Applied Optics, 58, 4390-4394(2019).
[22] D Shin, A Kirmani, V K Goyal, et al. Photon-efficient computational 3-D and reflectivity imaging with single-photon detectors. IEEE Trans on Computational Imaging, 1, 112-125(2015).
