[1] Albota M A, Aull B F, Fouche D G, et al. Three-dimensional imaging laser radars with Geiger-mode avalanche photodiode arrays[J]. Lincoln Laboratory Journal, 2002, 13(2): 351–370.

[2] Warburton R E, McCarthy A, Wallace A M, et al. Subcentimeter depth resolution using a single-photon counting time-of-flight laser ranging system at 1550 nm wavelength[J]. Optics Letters, 2007, 32(15): 2266–2268.

[3] O’Brien M E, Fouche D G. Simulation of 3d laser radar sys-tems[J]. Lincoln Laboratory Journal, 2005, 15(1): 37–60.

[4] Stone W C, Juberts M, Dagalakis N G, et al. Performance anal-ysis of Next-Generation ladar for manufacturing, Construction, and Mobility[R]. NIST, 2007: 7112–7117.

[6] Prochazka I, Kodet J, Blazej J, et al. Photon counting detector for space debris laser tracking and lunar laser ranging[J]. Ad-vances in Space Research, 2014, 54(4): 755–758.

[7] Vacek M, Michalek V, Peca M, et al. Photon counting Lidar for deep space applications: concept and simulator[J]. Proceeding of SPIE, 2013, 8773: 877309.

[8] Markus T, Neumann T, Martino A, et al. The ice, cloud, and land elevation satellite-2 (ICESat-2): science requirements, concept, and implementation[J]. Remote Sensing of Environment, 2017, 190: 260–273.

[9] Liu B, Yu Y, Chen Z, et al. True random coded photon counting Lidar[J]. Opto-Electronic Advances, 2020, 3(2): 190044.

[10] Mccarthy A, Collins R J, Krichel N J, et al. Long-range time-of-flight scanning sensor based on high-speed time-correlated single-photon counting[J]. Applied Optics, 2009, 48(32): 6241–6251.

[11] Du BC,Pang CK,Wu D, et al. High-speed photon-counting laser ranging for broad range of distances[J]. Scientific Reports, 2018, 8(1): 4198.

[12] LiangM,HuangJH,RenM, et al. 1550-nm time-of-flight ranging system employing laser with multiple repetition rates for reduc-ing the range ambiguity[J]. Optics Express, 2014, 22(4): 4662–4670.

[13] Zhang Q, Soon H W, Tian H T, et al. Pseudo-random single photon counting for time-resolved optical measurement[J]. Op-tics Express, 2008, 16(17): 13233–13239.

[14] Zhang Q, Chen L, Chen N G, et al. Pseudo-random single pho-ton counting: a high-speed implementation[J]. Biomedical Optics Express, 2010, 1(1): 41–46.

[15] Takeuchi N, Sugimoto N, Baba H, et al. Random modulation CW Lidar[J]. Applied Optics, 1983, 22(9): 1382–1386.

[16] Hiskett P A, Parry C S, Mccarthy A, et al. A photon-counting time-of-flight ranging technique developed for the avoidance of range ambiguity at gigahertz clock rates[J]. Optics Express, 2008, 16(18): 13685–13698.

[17] Krichel N J, Mccarthy A, Buller G S. Resolving range ambiguity in a photon counting depth imager operating at kilometer dis-tances[J]. Optics Express, 2010, 18(9): 9192–9206.

[18] Rieger P, UllrichA. Anovel range ambiguity resolutiontechnique applying pulse-position modulation in time-of-flight ranging ap-plications[J]. Proceedings of SPIE, 2012, 8389: 83790R.

[19] Zhang Y F, He Y, Yang F, et al. Three-dimensional imaging Lidar system based on high speed pseudorandom modulation and photon counting[J]. Chinese Optics Letters, 2016, 14(11): 111101.

[20] Yang F, Zhang F, He F, et al. High speed pseudorandom mod-ulation fiber laser ranging system[J]. Chinese Optics Letters, 2014, 12(8): 082801.

[21] Oh M S, Kong H J, Kim T M, et al. Reduction of range walk error in direct detection laser radar using a Geiger mode avalanche photodiode[J]. Optics Communications, 2010, 283(2): 304–308.

[22] Gatt P, Johnson S, Nichols T, et al. Geiger-mode avalanche photodiode ladar receiver performance characteristics and de-tection statistics[J]. Applied Optics, 2009, 48(17): 3261–3276.