[1] WRIGHT M W, KOVALIK J, MORRIS J et al. LEO-to-ground optical communications link using adaptive optics correction on the OPALS downlink[C], 9739(2016).

[2] WRIGHT M W, MORRIS J F, KOVALIK J M et al. Adaptive optics correction into single mode fiber for a low Earth orbiting space to ground optical communication link using the OPALS downlink[J]. Optics Express, 23, 33705-33712(2015).

[3] HEINE F, SAUCKE K, TROENDLE D et al. Laser based bi-directional Gbit ground links with the Tesat transportable adaptive optical ground station[C], 10096, 251-258(2017).

[4] SAUCKE K, SEITER C, HEINE F et al. The Tesat transportable adaptive optical ground station[C], 973906(20169739).

[5] [5] 徐月， 刘超， 兰斌， 等. 自适应光学在星地激光通信中的研究进展［J］. 激光与光电子学进展， 2023， 60（5）： 3788/LOP220582. doi: 10.3788/LOP220582XUY， LIUCH， LANB， et al. Research progress of adaptive optics in satellite-to-ground laser communication［J］. Laser & Optoelectronics Progress， 2023， 60（5）： 3788/LOP220582.（in Chinese）. doi: 10.3788/LOP220582

[6] [6] 芮道满， 刘超， 陈莫， 等. 自适应光学技术在星地激光通信地面站上的应用［J］. 光电工程， 2018， 45（3）： 170647. doi: 10.12086/oee.2018.170647RUID M， LIUCH， CHENM， et al. Application of adaptive optics on the satellite laser communication ground station［J］. Opto-Electronic Engineering， 2018， 45（3）： 170647.（in Chinese）. doi: 10.12086/oee.2018.170647

[7] [7] 刘超， 陈善球， 廖周， 等. 自适应光学技术在通信波段对大气湍流的校正［J］. 光学 精密工程， 2014， 22（10）： 2605-2610. doi: 10.3788/ope.20142210.2605LIUCH， CHENSH Q， LIAOZH， et al. Correction of atmospheric turbulence by adaptive optics in waveband of free-space coherent laser communication［J］. Opt. Precision Eng.， 2014， 22（10）： 2605-2610.（in Chinese）. doi: 10.3788/ope.20142210.2605

[8] [8] 陈莫. 基于大口径望远镜的星地激光通信地面站关键技术研究［D］. 成都： 中国科学院光电技术研究所， 2019.CHENM. Research on the Key Technologies of Large Aperture Telescope Ground Station for Satellite-to-ground Laser Communications［D］.Chengdu： Institute of Optics and Electronics， Chinese Academy of Sciences， 2019. （in Chinese）

[9] OSBORN J, TOWNSON M J, FARLEY O J D et al. Adaptive Optics pre-compensated laser uplink to LEO and GEO[J]. Optics Express, 29, 6113-6132(2021).

[10] MARTÍNEZ N, RODRÍGUEZ-RAMOS L F, SODNIK Z. Toward the uplink correction: application of adaptive optics techniques on free-space optical communications through the atmosphere[J]. Optical Engineering, 57(2018).

[11] MARTÍNEZ REY N, RODRÍGUEZ RAMOS L F, SODNIK Z. Uplink wavefront corrector system： from paper to reality[J]. Optics Express, 28, 5886-5897(2020).

[12] LEONHARD N, BERLICH R, MINARDI S et al. Real-time adaptive optics testbed to investigate point-ahead angle in pre-compensation of Earth-to-GEO optical communication[J]. Optics Express, 24, 13157(2016).

[13] BRADY A, BERLICH R, LEONHARD N et al. Experimental validation of phase-only pre-compensation over 494  m free-space propagation[J]. Optics Letters, 42, 2679-2682(2017).

[14] BRADY A, RÖSSLER C, LEONHARD N et al. Validation of pre-compensation under point-ahead-angle in a 1 km free-space propagation experiment[J]. Optics Express, 27, 17840-17850(2019).

[15] YANG H Z, BHARMAL N A, MYERS R M. Projected Pupil Plane Pattern： an alternative LGS wavefront sensing technique[J]. Monthly Notices of the Royal Astronomical Society, 477, 4443-4453(2018).

[16] TEAGUE M R. Deterministic phase retrieval： a Green's function solution[J]. Journal of the Optical Society of America, 73, 1434-1441(1983).

[17] RODDIER F. Curvature sensing and compensation： a new concept in adaptive optics[J]. Applied Optics, 27, 1223-1225(1988).

[18] GUREYEV T E, NUGENT K A. Phase retrieval with the transport-of-intensity equation II Orthogonal series solution for nonuniform illumination[J]. Journal of the Optical Society of America A, 13, 1670-1682(1996).

[19] ZHANG Z Y, YANG H Z, LIANG Y H. A new wavefront sensing technique for satellite-ground laser communication[C], 17, 2022(2022).