[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](2016).

[2] WRIGHT M W, MORRIS J, KOVALIK J 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, 100960Y(2017).

[4] SAUCKE K, SEITER C, HEINE F et al. The Tesat transportable adaptive optical ground station[C], 9739, 973906(2016).

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

[6] MARTINEZ N, RODRIGUEZ 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, 076106(2018).

[7] MARTINEZ N, RODRIGUEZ L F, SODNIK Z. Uplink wavefront corrector system: from paper to reality[J]. Optics Express, 28, 5886-5897(2020).

[8] ZHANG Zhenyu, YANG Huizhe, LIANG Yonghui. A new wavefront sensing technique for satellite-ground laser communication[C], 12185(2022).

[9] YANG Huizhe, ZHANG Zhenyu, LIN Jin et al. Wavefront sensing for FSO systems based on projected pupil plane pattern[J]. Optics and Precision Engineering, 32, 945-955(2024).

[10] VISHNIAKOU I, JOHANNES D S. Wavefront correction for adaptive optics with reflected light and deep neural networks[J]. Optics Express, 28, 15459-15471(2020).

[11] WANG K, ZHANG M, TANG J et al. Deep learning wavefront sensing and aberration correction in atmospheric turbulence[J]. PhotoniX, 2, 8(2021).

[12] JIA Peng, MA Mingyang, CAI Dongmei et al. Compressive Shack-Hartmann wavefront sensor based on deep neural networks[J]. Monthly Notices of the Royal Astronomical Society, 503, 3194-3203(2021).

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

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

[15] GOODMAN J[M]. Introduction to Fourier Optics 3^rd edition(2005).

[16] SCHMIDT D J. Numerical simulation of optical wave propagation with examples in MATLAB[M]. SPIE(2010).

[17] XU Yue, LIU Chao, LAN Bin et al. Research progress of adaptive optics in satellite-to-ground laser communication[J]. Laser & Optoelectronics, 60, 0500004(2023).

[18] SIMONYAN K, ZISSERMAN A. Very deep convolutional networks for large-scale image recognition[C], 1-14(2015).

[19] HE K, ZHANG X, REN S et al. Deep residual learning for image recognition[C], 770-778(2016).

[20] VASWANI A, SHAZEER N, PARMAR N et al. Attention is all you need[J]. Advances in Neural Information Processing Systems, 30, 5998-6008(2017).

[21] LIU Z, LIN Y, CAO Y et al. Swin transformer: Hierarchical vision transformer using shifted windows[C], 10012-10022(2021).

[22] LIU Z. Swin transformer V2: scaling up capacity and resolution[C], 11999-12009(2022).

[23] DIEDERIK P K, JIMMY B. Adam: a method for stochastic optimization[C], 13(2015).

[24] BOTTOU L[M]. Stochastic gradient descent tricks, 421-436(2012).