[1] CAO Hengying, CHEN Heming, BAI Xiuli. Generation and multiplexing of photon orbital angular momentum based on silicon-based waveguide[J]. Acta Photonica Sinica, 48, 1248003(2019).

[2] ZHANG Junwei, LIU Junyi, SHEN Lei et al. Mode-division multiplexed transmission of wavelength-division multiplexing signals over a 100-km single-span orbital angular momentum fiber[J]. Photonics Research, 8, 1236-1242(2020).

[3] ZHANG Dongxiao, CHEN Zhibin, XIAO Cheng et al. High precision generation method of turbulent phase screen based on modified atmospheric spectrum[J]. Acta PHOTONICA Sinica, 49, 0601002(2020).

[4] LI Xin, WU Yang, FANG Zhou et al. Adaptive optics image post-processing based on multi-channel blind recognition[J]. Acta Photonica Sinica, 49, 0201003(2020).

[5] JIANG Jisong, JIANG Aimin. Numerical model and verification of non isohalo imaging based on time-varying phase screen[J]. Acta Photonica Sinica, 49, 0301001(2020).

[6] CUI Suying, ZHAO Xiaohui, HE Xu et al. A quick hybrid atmospheric-interference compensation method in a WFS-less free-space optical communication system[J]. Current Optics and Photonics, 2, 612-622(2018).

[7] JIANG Jie, GUO Hongxiang, BIAN Yiming. et al Dynamic turbulence compensation simulation of few mode fiber coupling demultiplexing system based on SPGD algorithm[J]. Acta Optica Sinica, 41, 1901001(2021).

[8] LI Qian, WU Zhen, XU Jiesu et al. Phase restoration algorithm based on pupil difference[J]. Acta Optica Sinica, 39, 0626001(2019).

[9] HU Qintao, ZHEN Liangli, MAO Yao et al. Adaptive stochastic parallel gradient descent approach for efficient fiber coupling[J]. Optics Express, 28, 13141-13154(2020).

[10] LIANG Wei, ZHOU Feng, HE Jun et al. Research on vortex beam distortion wavefront correction technology based on genetic algorithm[J]. Journal of Hunan Institute of Technology (Natural Science Edition), 34, 47-51(2021).

[11] PAINE S W, FIENUP J R. Machine learning for improved image-based wavefront sensing[J]. Optics Letters, 43, 1235-1238(2018).

[12] TIAN Qinghua, LU Chenda, LIU Bo et al. DNN-based aberration correction in a wavefront sensorless adaptive optics system[J]. Optics Express, 27, 10765-10776(2019).

[13] YOHEI N, MATIAS V, RYOICHI H et al. Deep learning wavefront sensing[J]. Optics Express, 27, 240-251(2019).

[14] ZHAI Yanwang, FU Shiyao, ZHANG Jianqiang et al. Turbulence aberration correction for vector vortex beams using deep neural networks on experimental data[J]. Optics Express, 28, 7515-7527(2020).

[15] MA Huimin, LIN Haiqiu, QIAO Yan et al. Numerical study of adaptive optics compensation based on convolutional neural networks[J]. Optics Communications, 433, 283-289(2019).

[16] MA Huimin, JIAO Jun, QIAO Yan et al. A wavefront restoration method based on deep learning of light intensity images[J]. Laser & Optoelectronics Progress, 57, 081103(2020).

[17] WU Yu, GUO Youming, BAO Hua et al. Sub-millisecond phase retrieval for phase-diversity wavefront sensor[J]. Sensors, 20, 4877(2020).

[18] ZHANG Yang, HE Yulong, NING Yu et al. Deep learning method of far-field spot inversion wavefront phase[J]. Infrared and Laser Engineering, 50, 20200363(2021).

[19] LI Xiang, WANG Wenhai, HU Xiaolin et al. Selective kernel networks[C], 510-519(2019).

[20] ZAGORUYKO S, KOMODAKIS N. Paying more attention to attention: improving the performance of convolutional neural networks via attention transfer[C](2017).

[21] ZHANG Danyu. Adaptive optics wavefront distortion control and experimental research[D](2020).