[1] Abbott B P, Abbott R, Abbott T D et al. Observation of gravitational waves from a binary black hole merger[J]. Physical Review Letters, 116, 061102(2016).

[2] Wanner G. Space-based gravitational wave detection and how LISA Pathfinder successfully paved the way[J]. Nature Physics, 15, 200-202(2019).

[3] Luo Z R, Zhang M, Jin G et al. Introduction of Chinese space-borne gravitational wave detection program “Taiji” and “Taiji-1” satellite mission[J]. Journal of Deep Space Exploration, 7, 3-10(2020).

[4] Luo Z R, Bai S, Bian X et al. Gravitational wave detection by space laser interferometry[J]. Advances in Mechanics, 43, 415-447(2013).

[5] Luo J, Chen L S, Duan H Z et al. TianQin: a space-borne gravitational wave detector[J]. Classical and Quantum Gravity, 33, 035010(2016).

[6] Dong Q R, Chen T, Gao S J et al. Progress of research on satellite-borne laser communication technology[J]. Chinese Optics, 12, 1260-1270(2019).

[7] Liu L R. Laser communications in space Ⅰ: optical link and terminal technology[J]. Chinese Journal of Lasers, 34, 3-20(2007).

[8] Tolker-Nielsen T, Oppenhauser G. In-orbit test result of an operational optical intersatellite link between ARTEMIS and SPOT4, SILEX[J]. Proceedings of SPIE, 4635, 1-15(2002).

[9] Wuchenich D M R, Mahrdt C, Sheard B S et al. Laser link acquisition demonstration for the GRACE Follow-on mission[J]. Optics Express, 22, 11351-11366(2014).

[10] Zhang R F, Zhang W R, Zhang X J et al. Research status and development trend of high earth orbit satellite laser relay links[J]. Laser & Optoelectronics Progress, 58, 0500001(2021).

[11] Xu M, Shi H D, Wang C et al. Technology for integrating space object multidimensional detection and laser communication[J]. Chinese Journal of Lasers, 48, 1206002(2021).

[12] Bai Y Y, Cen Y Y, Meng L X et al. Control technology of slave optical transceiver in space laser communication network[J]. Acta Optica Sinica, 41, 1406001(2021).

[13] Maghami P G, Hyde T T, Kim J. An acquisition control for the laser interferometer space antenna[J]. Classical and Quantum Gravity, 22, S421-S428(2005).

[14] Cirillo F. Controller design for the acquisition phase of the LISA mission using a Kalman filter[D](2007).

[15] Cirillo F, Gath P F. Control system design for the constellation acquisition phase of the LISA mission[J]. Journal of Physics: Conference Series, 154, 012014(2009).

[16] Dong Y H, Liu H S, Luo Z R et al. Principle demonstration of fine pointing control system for inter-satellite laser communication[J]. Science China Technological Sciences, 58, 449-453(2015).

[17] Gao R H, Liu H S, Zhao Y et al. Laser acquisition experimental demonstration for space gravitational wave detection missions[J]. Optics Express, 29, 6368-6383(2021).

[18] Gao R H. The research on the laser acquisition-pointing technique of inter-satellite interferometer for the space-based gravitational wave detection[D](2020).

[19] Dong Y H. Research on precise pointing and low-light phase-locked control technology for gravitational wave detection by space laser interference[D], 16-19(2015).

[20] Luo Z R, Wang Q L, Mahrdt C et al. Possible alternative acquisition scheme for the gravity recovery and climate experiment follow-on-type mission[J]. Applied Optics, 56, 1495-1500(2017).

[21] Chen X L, Zheng Y H, Wang Y. Influence of spot noise in inter-satellite optical communications and suppression algorithm[J]. Chinese Journal of Lasers, 37, 743-747(2010).

[22] Zhao Q, Hao S Q, Zhang D. Location method of spot center based on improved threshold segmentation[J]. Laser & Infrared, 48, 633-637(2018).

[23] Wu F, Yu S Y, Zhou J et al. Analysis of the stability of bidirectional beam tracking in inter-satellite optical communication[J]. Chinese Journal of Lasers, 40, 1105003(2013).

[24] Huang H B. Research on key technology of servo control of composite photoelectric precision tracking[D], 94-95(2011).