[1] LI Zhu-Lian, Zhai Dong-Sheng, Zhang Hai-Tao et al. Superconductivity detector applied to daytime satellite laser ranging experiment and research[J]. Infrared and Laser Engineering, 49, 127-132(2020).

[2] LI Ming, XUE Li, HUANG Chen et al. Estimation of detection range for space debris laser ranging system based on efficient echo probability[J]. Optics and Precision Engineering, 24, 260-267(2016).

[3] DENG Hua-Rong, LONG Ming-Liang, ZHANG Hai-Feng et al. Experiment of satellite laser ranging in daytime based on 1064nm wavelength[J]. Infrared and Laser Engineering, 49, 134-139(2020).

[4] LONG Ming-Liang, ZHANG Hai-Feng, Lin-Lin MEN et al. Satellite laser ranging at 10 kHz repetition rate in all day[J]. J. Infrared Millim.WavesJ. Infrared Millim.Waves, 39, 778-785(2020).

[5] LI Xin, WANG Pei-Yuan, ZOU Tongal et. Experiment on kHz laser ranging at Wuhan satellite laser ranging station[J]. High Power Laser and Particle Beams, 23, 367-370(2011).

[6] Kirchner G, Koidl F. Laser Ranging to Space Debris from Graz Laser Station[J]. VGI, 103, 151-155(2015).

[7] Kucharski D, Otsubo T, Kirchner Gal et. Spin axis orientation of Ajisai determined from Graz2kHz SLR data[J]. Advances in Space Research, 46, 251-256(2010).

[8] Kucharski D, Kirchner G, Koidl F. Spin parameters of nanosatellite BLITS determined from Graz 2 kHz SLR data[J]. Advances in Space Research, 48, 343-348(2011).

[9] DENG Hua-Rong, ZHANG Hai-Feng, LONG Ming-Liang et al. 4 kHz Repetition rate satellite laser ranigng system and its application[J]. Acta Optica Sinica, 39, 225-231(2019).

[10] Steindorfer M A, Kirchner G, Koidl F et al. Daylight space debris laser ranging[J]. Nature Communications, 11, 1-6(2020).

[11] Degnan J J, Mcgarry J F. SLR2000: Eyesafe and autonomous single photoelectron satellite laser ranging at kilohertz rates[J]. Proceedings of Spie the International Society for Optical Engineering, 3218, 63-77(1997).

[12] Isyanova Y, Wall K F, Flint J H et al. High-power, short-pulse, compact SLR2000 laser transmitter[J], MB14(2004).

[13] Degnan J J. SLR2000 technical overview, status, and schedules[J].

[14] Lim H C, Sung K P, Yu S Y et al. Satellite laser ranging system at Geochang station[J]. Journal of Astronomy and Space Science, 35, 253-261(2018).

[15] Lim H, Choi M, Park E et al. Technical Aspects and Progress of Korean SLR Systems[C](2013).

[16] Choi E J, Bang S C, Sung K P et al. Design and Development of High-Repetition-Rate Satellite Laser Ranging System[J]. Journal of Astronomy and Space Science, 32, 209-219(2015).

[17] Mei Jianwei, Bai Yan-Zheng, Bao Jiahui et al. The TianQin project: current progress on science and technology[J]. Progress of Theoretical and Experimental Physics, 05-107(2021).

[18] Tang Mei-Rong, Li Zhu-Lian, Li Yu-Qiang et al. Influence of Atmospheric Turbulence Intermittency on Return Photon Number in Laser Ranging[J]. Acta Optica Sinica, 037, 1-7(2017).

[19] Han Guang-Yu, Ju Feng, Guo Jin et al. Analysis and realization of day-time ranging of SLR[J]. Chinese Journal of Scientific Instrument, 885-890(2012).

[20] Degnan J. J.. “SLR 2000” in Satellite Laser Ranging in the 1990’s: Report of the 1994 Belmont Workshop[C], 3283, 101-106(1994).

[21] Kucharski D, Kirchner G, Lim H C et al. Spin parameters of High Earth Orbiting satellites Etalon-1 and Etalon-2 determined from kHz Satellite Laser Ranging data[J]. Advances in Space Research, 54, 2309-2317(2014).

[22] Kirchner G, Koidl F. Graz kHz SLR system: design, experiences and results[C], 501-505(2004).

[23] Guo T, Wang P, Li X et al. Progress of the satellite laser ranging system TROS1000[J]. Geodesy and Geodynamics, 6, 67-72(2015).

[24] Wang P, Steindorfer M A, Koidl F et al. Megahertz repetition rate satellite laser ranging demonstration at Graz observatory[J]. Optics Letters, 46, 937-940(2021).