[1] Qiang FU, Huilin JIANG, Xiaoman WANG. Research status and development trend of space laser communication. Chinese Optics, 5, 116-125(2012).
[2] Chunyi CHEN, Huamin YANG, Huilin JIANG. Research progress of mitigation technologies of turbulence effects in atmospheric optical communication. Acta Armamentarii, 30, 779-791(2009).
[3] H YAO, Y CAO, W WANG et al. A computational model of cn2 profile inversion for atmospheric laser communication in the vertical path. Sensors, 23, 5874(2023).
[4] Yingchi GUO, Lang LI, Chen LI. Atmospheric optical turbulence prediction method for satellite-ground laser communication (invited). Infrared and Laser Engineering, 53, 20230729(2024).
[5] Ruizhong RAO. Analysis and prospect of modern atmospheric optics and its applications in optoelectronic engineering (invited). Infrared and Laser Engineering, 51, 20210818(2022).
[6] Caiyu WANG, Kee YUAN, Dongfeng SHI. Simulation of atmospheric turbulence profile measured by differential wavefront lidar. Acta Optica Sinica, 41, 1001002(2021).
[7] Lei ZHANG, Xin ZHAO, Shoufeng TONG. Measurement of atmospheric turbulence parameters on airborne platform based on differential image motion method. Chinese Journal of Lasers, 44, 0304002(2017).
[8] B DIBAEE, R SHOMALI, J KHALILZADEH et al. 4-aperture differential image motion monitor as a new approach for estimating atmospheric turbulence parameters. Journal of Modern Optics, 66, 753-763(2019).
[9] Ziyue WANG, Deqing REN. Improved to differential image motion monitor. Astronomical Research and Technology, 16, 114-122(2019).
[10] M PANAHI, R SHOMALI, M MOLLABASHI et al. Atmospheric coherence time measurement by four-aperture DIMM defocus velocity technique. Applied Optics, 58, 8673-8679(2019).
[11] R HANNA, D M BROWN, A BROWN et al. Measuring atmospheric turbulence along folded paths using a laser-illuminated differential image motion monitor. Applied Optics, 61, 9646-9653(2022).
[12] Chenxiang QIU, Zaihong HOU, Xu JING. Turbulence models and daily variations obtained by bidirectional atmospheric coherent length measurements. Acta Optica Sinica, 42, 0901002(2022).
[13] Junxin ZHANG, Haiping MEI, Yichong REN. Fold-path atmospheric coherence length measurement by laser-active illumination imaging. Acta Optica Sinica, 43, 1201003(2023).
[14] Yang SHA, Xu JING, Yi WU. Influence of signal to noise ratio on atmospheric coherence length measured by DIMM. Journal of Atmospheric and Environmental Optics, 13, 178(2018).
[15] D L FRIED. Optical resolution through a randomly inhomogeneous medium for very long and very short exposures. JOSA, 56, 1372-1379(1966).
[16] SARAZIN M, RODDIER F. The ESO differential image motion monit[J]. Astronomy Astrophysics , 1990, 227(1): 294300.
[17] AO J, LIU J, MA C. A new measurement of atmospheric coherent length using differential image motion[C]2016 11th International Symposium on Antennas, Propagation EM They (ISAPE). IEEE, 2016: 264267.
[18] MACQUEEN J. Some methods f classification analysis of multivariate observations[C]Proceedings of the Fifth Berkeley Symposium on Mathematical Statistics Probability, 1967, 1(14): 281297.
[19] DUDA R O, HART P E, STK D G. Pattern Classification Scene Analysis[M]. New Yk: Wiley, 1973.
[20] H YAO, Q HAO, C CHEN et al. Generation of temporal fading envelope sequences for the FSOC channel based on atmospheric turbulence optical parameters. Optics Express, 30, 34519(2022).
