[1] D Lucchesi, L Anselmo, M Bassan, et al. General relativity measurements in the field of earth with laser-ranged satellites: state of the art and perspectives. Universe, 5, 141(2019).
[2] E J Choi, S C Bang, K P Sung, et al. Design and development of high-repetition-rate satellite laser ranging system. Journal of Astronomy and Space Sciences, 32, 209-219(2015).
[3] I Prochazka, J Kodet, J Blazej, et al. Identification and calibration of one-way delays in satellite laser ranging systems. Advances in Space Research, 59, 2466-2472(2017).
[4] M R Pearlman, C E Noll, E C Pavlis, et al. The ILRS: Approaching 20 years and planning for the future. Journal of Geodesy, 93, 2161-2180(2019).
[5] Huarong Deng, Zhingbo Wu, Pu Li, et al. Improvement research on SLR data deviation by using polarization technology for energy regulation. Infrared and Laser Engineering, 46, 0917005(2017).
[6] Bo Liu, Nianjiang Chen, Zhongping Zhang, et al. Technology of micro-pulse satellite laser ranging. Infared and Laser Engineering, 37, 234-237(2008).
[7] B Meisel, D Angermann, M Krügel, et al. Refined approaches for terrestrial reference frame computations. Advances in Space Research, 36, 350-357(2005).
[8] Renjie Ding, Zhibo Wu, Huarong Deng, et al. Research and design of high automation satellite laser ranging system. Laser & Infrared, 47, 1102-1107(2017).
[9] R Zajdel, K Sośnica, M Drożdżewski, et al. Impact of network constraining on the terrestrial reference frame realization based on SLR observations to LAGEOS. Journal of Geodesy, 93, 2293-2313(2019).
[10] Trence M H, Klosko S M, Christodoulidis D C. The construction testing of nmal points at goddard space flight center[C]Proceedings of 5th International Wkshop on Laser Ranging Instrumentation, 1984: 506516.
[11] Appleby G M, Sinclair A. Fmation of onsite nmal points[C] Proceedings of 8th International Wkshop on Laser Ranging Instrumentation, 1992, 9: 1925.
[12] Conklin B M, Davis D, Edge V, et al. NSLR PC software packages f nmal point acquisition generation[C] Proceedings of the 9th International Wkshop on Laser Ranging Instrumentation, 1994: 10901095.
[13] Paunonen M. Adaptive median filtering f preprocessing of time series measurements[C]Proceedings of the 8th International Wkshop on Laser Ranging Instrumentation, 1992, 2: 4450.
[14] Sinclair A T. Restatement of herstmonceux nmal point recommendation[ROL]. 1997. https:ilrs.gsfc.nasa.govdata__productsdatanptnpt_algithm.html.
[15] Sinclair A T. Neubert R, Appleby G M. The LAGEOS centre of mass crection f different detection techniques[C]Proceedings of Annual Eurolas Meeting, 1995: 3136.
[16] Seemüller, W W. Missions wking group rept[C]Proceedings of Seventh General Assembly of ILRS, 2002.
[17] Appleby G, Deleflie F, Desch N, et al. ILRS governing board meeting rept[R].Vienna, Austria: EGU General Assembly, 2012.
[18] Clarke C B, Degnan J J, McGarry J F, et al. Processing single photon data f maximum range accuracy[C]Proceedings of the 18th International Wkshop on Laser Ranging Instrumentation, 2013.
[19] Degnan J J. A data processing approach to high precision, high return rate kHz SLR stations[C]Proceedings of the 21th International Wkshop on Laser Ranging Instrumentation, 2018.
[20] C E Noll, R Ricklefs, J Horvath, et al. Information resources supporting scientific research for the international laser ranging service. Journal of Geodesy, 93, 2211-2225(2019).
[21] Bayer I, Gibbs P, Wilkinson M. Herstmonceux time bias system as a possible realtime QC tool[C]Proceedings of the 14th International Wkshop on Laser Ranging Instrumentation, 2004.
[22] Wenyun Kang, Xiaoquan Song, Zhen Wei. Weak signal detecting method of laser ranging for space target in daytime. Infrared and Laser Engineering, 43, 3026-3029(2014).
[23] Bohui Cheng, Zhibin Wei, Feng Qu, et al. The realization of daytime laser ranging on Beijing satellite laser observatory. Bulletin of Surveying and Mapping, 58-60(2015).
[24] Gurtner W, Pop E, Utzinger J. Improvements in the Automation of the Zimmerwald SLR Station[C]Proceedings of the 13th International Wkshop on Laser Ranging Instrumentation, 2002.
[25] Zhongping Zhang. Screen preprocess method for SLR data. Annals of Shanghai Observatory Academia Sinca, 118-125(1993).
[26] Dong Xue. Research of high repetition space debris laser ranging system[D]. Changchun: Graduate School of Chinese Academy of Sciences(Changchun Institute of Optics, Precision Mechanics Physics, Chinese Academy of Sciences), 2014. (in Chinese)
[27] Heiner M, Schreiber U, Brl N. Recursive filter algithm f noise reduction in SLR[C]Proceedings of the 15th International Wkshop on Laser Ranging Instrumentation, 2006.
[28] Ricklefs R L, Shelus P J. Poisson filtering of laser ranging data[C]Proceedings of the 8th International Wkshop on Laser Ranging Instrumentation, 1992, 9: 2633.
[29] Rodriguez J, Appleby G, Otsubo T, et al. Assessing enfcing singlephoton returns: poisson filtering[C]Proceedings of the 20th International Wkshop on Laser Ranging Instrumentation, 2016.
[30] Clarke C B, Degnan J J, Mcgarry J F, et al. Background noise suppression f increased data acceptance[C]Proceedings of the 19th International Wkshop on Laser Ranging Instrumentation, 2014.
[31] Eckl J J, Schreiber K U. Single photon tracking under difficult condition[C]Proceedings of 2015 ILRS Technical Wkshop, 2015.
[32] Yanyu Liu, Xiaoping Wu, Hao Gao, et al. Data pre-processing algorithm of satellite laser ranging based on curve recognition from points cloud. Journal of Geodesy and Geodynamics, 31, 105(2011).
[33] Xi Li, Rufeng Tang, Zhulian Li, et al. Laser ranging data processing based on the analysis of the binary image. Chinese Journal of Lasers, 41, 1208005(2014).
[34] Li Xue, Zhu Zhaokun, Wu Wentang, et al. Simulated analysis of processing satellite laser ranging data using neural wks trained by DeepLabCut[C]Processings of the 2019 IEEE 5th International Conference on Computer Communiactions, 2019: 468472.
[35] T Otsubo, R A Sherwood, G M Appleby, et al. Center-of-mass corrections for sub-cm-precision laser-ranging targets: Starlette, Stella and LARES. Journal of Geodesy, 89, 303-312(2014).
[36] Fitzmaurice M W, Minott P, Abshire J B, et al. Prelaunch testing of the laser geodynamic satellite (LAGEOS): NASATP1062, G7702F16[ROL]. NASA, 1977: 1.
[37] Neubert R. An analytical model of satellite signature effects[C]Proceedings of 9th International Wkshop on Laser Ranging Instrumentation, 1994: 8291.
[38] Jianxing Fan, Fumin Yang, Qixiu Chen. Center-of-mass of satellites used for laser ranging. Acta Photonica Sinica, 29, 1012-1016(2000).
[39] T Otsubo, G M Appleby. System-dependent center-of-mass correction for spherical geodetic satellites. Journal of Geophysical Research: Solid Earth, 108, 2201-2210(2003).
[40] Yuan Liu, Ning An, Cunbo Fan, al at. Influence of shape effect of angle reflector on ranging precision of satellite lser ranging system. Laser & Optoelectronics Progress, 55, 110101(2018).
[41] Wilkinson M, Rodrguez J, Otsubo T, et al. Implementing consistent clipping in the reduction of SLR data from SGF, Herstmonceux[C]Proceedings of 21th International Wkshop on Laser Ranging Instrumentation, 2018.
[42] D Kucharski, G Kirchner, T Otsubo, et al. A method to calculate zero-signature satellite laser ranging normal points for millimeter geodesy-a case study with Ajisai. Earth, Planets and Space, 67, 34(2015).
[43] Riepl S, Blobfeld M, Schuler T. Processing of SLR observations with an optimal wiener filteran alternative way to calculate nmal points[C]Proceedings of 21th International Wkshop on Laser Ranging Instrumentation, 2018.
[44] Liu Yuan. Research on data processing method of high frequency laser ranging of spherical satellite[D]. Beijing: University of Chinese Academy of Sciences, 2019.
[45] E Samain, J F Mangin, C Veillet, et al. Millimetric Lunar Laser Ranging at OCA (Observatoire de la Côte d’Azur). Astronomy and Astrophysics Supplement Series, 130, 235-244(1998).
[46] Yun He, Qi Liu, Wei Tian, et al. Study on laser ranging for satellite on the second lagrange point of earth-moon system. Journal of Deep Space Exploration, 4, 131-137(2017).
[47] Zhibo Wu, Huarong Deng, Haifeng Zhang, et al. Interference and avoidance of atmospheric backscattering on satellite laser ranging with high repetition rate. Infrared and Laser Engineering, 46, 0206002(2017).