[1] WANG Hongxing, WU Xiaojun, SONG Bo. Modeling and analysis of beam wander in maritime[J]. Chinese J Lasers, 43, 229-240(2016).

[2] WU Xiaojun, WANG Hongxing, LI Bifeng et al. Analysis of atmospheric refractive index structure paramer under the sea surface environment[J]. Acta Optica Sinica, 35, 17-26(2015).

[3] ZHU Wenyue, WANG Huihua, CHEN Xiaowei et al. Uncertainty analysis of evaluation of high power laser propagation in atmosphere[J]. Chinese Journal of Quantum Electronics, 37, 524-533(2020).

[4] WU Shuyun, LI Xinyang, LUO Xi. Numerical simulation of horizontal propagation steady-state thermal blooming effect on laser beam with different intensity distribution[J]. Opto-Electronic Engineering, 45, 53-65(2018).

[5] MA Kang, LIU Chuanbo. Test and evaluation method of the high-energy laser atmospheric transmission based on the detector array[J]. Optics & Optoelectronic Technology, 15, 16-20(2017).

[6] SUN Xingwang, ZHANG Qing, ZHONG Zheqiang et al. Scaling law for beam spreading during high-energy laser propagation in atmosphere[J]. Acta Optica Sinica, 42, 2401008(2022).

[7] HUANG Yinbo, WANG Yingjian. Numerical analysis of the scaling laws about focused beam spreading incluced by the atmosphere[J]. Acta Physica Sinica, 6715-6719(2006).

[8] QIAO Chunhong, FAN Chenyu, WANG Yingjian. Scaling laws about DF high energy laser propagation in real atmosphere[J]. High Power Laser and Particle Beams, 1965-1969(2007).

[9] CHEN Xiaowei, ZHU Wenyu, QIAN Xianmei et al. Scale model of focused Gaussian beam propagating in turbulent atmosphere[J]. Chinese J Lasers, 50, 109-118(2023).

[10] LU Jie, ZHU Wenyu, CAI Jun et al. Comparison of two approaches for estimating atmospheric optical turbulence intensity near sea[J]. Acta Optica Sinica, 37, 0501001(2017).

[11] LENG Kun, YANG Yuntao, HUANG Yanhua et al. Evaluation method of laser transmission efficiency based on small sample machine learning[J]. Journal of Army Engineering University of PLA, 3, 36-42(2024).

[12] LU Jie, ZHU Wenyu, QING Chun et al. Estimation of atmospheric optical turbulence at near surface of chengdu with support vector machin[J]. Chinese J Lasers, 45, 199-205(2018).

[13] LENG Kun, YANG Yuntao, TAN Zhe et al. Evaluation method of laser atmospheric propagation efficiency based on support vector machine[J]. Chinese Journal of Quantum Electronics, 37, 547-555(2020).

[14] TAN Zhe, GONG Yanchun, YANG Yuntao et al. A simulation study on atmospheric transmission effect evaluation of laser based on random forest[J]. Laser & Infrared, 52, 23-28(2022).

[15] [15] SU Changdong. Optical turbulence fecasting turbulence degraded image restation based on machine learning [D]. Hefei: University of Science Technology of China, 2022. (in Chinese)

[16] CUI Xun, CHEN Xiaowei, QIAN Xianmei et al. Study of fast calculation method of far-field radius for laser propagation through turbulent atmosphere[J]. Infrared and Laser Engineering, 53, 20240231(2024).

[17] ZHU Wenyue, QIAN Xianmei, RAO Ruizhong et al. Evaluation technology of high energy laser atmospheric propagation performance[J]. Infrared and Laser Engineering, 48, 1203002(2019).

[18] QIAO Chunhong, FAN Chenyu, HUANG Yinbo et al. Scaling laws of high energy laser propagation through atmosphere[J]. Chinese J Lasers, 37, 433-437(2010).

[19] QIAO Chunhong, FAN Chenyu, WANG Yingjian et al. Simulation experiment of high energy laser propagation in the atmosphere[J]. High Power Laser and Particle Beams, 20, 1811-1816(2008).

[20] WANG Yingjian, HUANG Yinbo. Analysis of the scaling laws about focused uniform beam spreading induced by real atmosphere[J]. Chinese Journal of Quantum Electronics, 274-281(2006).