[1] R H Hadfield. Single-photon detectors for optical quantum information applications. Nature Photonics, 3, 696-705(2009).

[2] M D Eisaman, J Fan, A Migdall, S V Polyakov. Invited review article: single-photon sources and detectors. Rev Sci Instrum, 82, 071101(2011).

[3] J Zhang, M A Itzler, H Zbinden, et al. Advances in InGaAs/InP single-photon detector systems for quantum communication. Light-Science & Applications, 4, e286(2015).

[4] Kameyama S, Yanagisawaa T, o T, et al. Development of wind sensing coherent Doppler LIDAR at Mitsubishi Electric Cpationfrom late 1990 s to 2013[C]Proceedings of 17th Coherent Laser Radar Conference, Barcelona, Spain. 2013.

[5] C M Natarajan, M G Tanner, R H Hadfield. Superconducting nanowire single-photon detectors: physics and applications. Superconductor Science and Technology, 25, 063001(2012).

[6] A Vandevender, P Kwiat. High efficiency single photon detection via frequency up-conversion. Journal of Modern Optics, 51, 1433-1445(2004).

[7] G L Shentu, J S Pelc, X D Wang, et al. Ultralow noise up-conversion detector and spectrometer for the telecom band. Opt Express, 21, 13986-13991(2013).

[8] Zhang J, Eraerds P, Walenta N, et al. 2.23 GHz gating InGaAsInP singlephoton avalanche diode f quantum key distribution[EBOL].(20100217)[20230110]. https:arxiv.gabs1002.3240.

[9] M A Itzler, X D Jiang, M Entwistle, et al. Advances in InGaAsP based avalanche diode single photon detectors. J Mod Opt, 58, 174-200(2011).

[10] J C Campbell. Recent advances in telecommunications avalanche photodiodes. J Lightw Technol, 25, 109-121(2007).

[11] G Ribordy, J D Gautier, H Zbinden, et al. Performance of InGaAs/InP avalanche photodiodes as gated-mode photon counters. Appl Opt, 37, 2272-2277(1998).

[12] Y Q Fang, W Chen, T H Ao, et al. InGaAs/InP single-photon detectors with 60% detection efficiency at 1550 nm. Review of Scientific Instruments, 91, 083102(2020).

[13] S Cova, M Ghioni, A Lacaita, et al. Avalanche photodiodes and quenching circuits for single-photon detection. Applied Optics, 35, 1956-1976(1996).

[14] Jiang X D, Itzler M A, Nyman B, Slomkowski K. Negative feedback avalanche diodes f nearinfrared single photon detection[C]Proc SPIE, 2009, 7320: 732011.

[15] Itzler M A, Jiang X D, Onat B M, Slomkowski K. Progress in selfquenching InPbased single photon detects[C]Proc SPIE, 2010, 7608: 760829.

[16] T Lunghi, C Barreiro, O Guinnard, et al. Free running single photon detection based on a negative feedback InGaAs APD. J Mod Opt, 59, 1481-1488(2012).

[17] Z Yan, D R Hamel, A K Heinrichs, et al. An ultra low noise telecom wavelength free running single photon detector using negative feedback avalanche diode. Rev Sci Instrum, 83, 073105(2012).

[18] C Yu, M J Shangguan, H Y Xia, et al. Fully integrated free-running InGaAs/InP single-photon detector for accurate lidar applications. Opt Express, 25, 14611-14620(2017).

[19] C Yu, J W Qiu, H Y Xia, et al. Compact and lightweight 1.5 μm lidar with a multi-mode fiber coupling free-running InGaAs/InP single-photon detector. Rev Sci Instrum, 89, 103106(2018).

[20] MPD. PDMIR[EBOL]. [20230110]. http:www.microphotondevices.comProductsPhotonCountersPDMIR

[21] IDQ. ID Qube NIR Gated[EBOL]. [20230110]. https:www.idquantique.comquantumsensingproductsidqubenirgated.

[22] J Zhang, R Thew, J D Gautier, et al. Comprehensive characterization of InGaAsP-InP avalanche photodiodes at 1550 nm with an active quenching ASIC. IEEE J Quantum Electron, 45, 792-799(2009).