[1] Kunyu TAO, Zhewei CAO, Qi YANG et al. Problems and solutions of ultra-high speed digital coherent space laser communication. Optical Communication Technology, 45, 44-49(2021).

[2] Duorui GAO, Zhuang XIE, Rong MA et al. Development current status and trend analysis of satellite laser communication (invited). Acta Photonica Sinica, 50, 0406001(2021).

[3] C GENG, F LI, J ZUO et al. Fiber laser transceiving and wavefront aberration mitigation with adaptive distributed aperture array for free-space optical communications. Optics Letters, 45, 1906-1909(2020).

[4] Qilai ZHAO, Zhitao ZHANG, Bo WU et al. Noise-sidebands-free and ultra-low-RIN 1.5 μm single-frequency fiber laser towards coherent optical detection. Photonics Research, 6, 326-331(2018).

[5] Lirun GAO, Zhan LI, Wenyan ZHANG et al. Enhanced negative group velocity propagation in optical fibers with a hybrid Brillouin lasing resonator. Optics Letters, 44, 5097-5100(2019).

[6] Lirun GAO, Zhan LI, Wenyan ZHANG et al. Group velocity control by gain-assisted fiber Mach-Zehnder interferometers. Applied Physics Express, 12, 092006(2019).

[7] H WU, Z WANG, W SUN et al. 1.5 μm low threshold, high efficiency random fiber laser with hybrid Erbium-Raman gain. Journal of Lightwave Technology, 36, 844-849(2018).

[8] V R SUPRADEEPA, W NICHOLSON JEFFREY. Power scaling of high-efficiency 1.5 μm cascaded Raman fiber lasers. Optics Letters, 38, 2538-2541(2013).

[9] Yongchuan XIAO, Chao WANG, Hao ZHANG et al. Improvement of transmission efficiency in microwave photonic links using EDFA. Chinese Optics, 13, 995-1000(2020).

[10] Zihang ZHU, Shanghong ZHAO, Yongjun LI et al. Optimization of optically pre-amplified inter-satellite microwave photonic links. Journal of Optoelectronics · Laser, 24, 500-507(2013).

[11] L V KOTOV, M E LIKHACHEV, M M BUBNOV et al. Yb-free Er-doped all-fiber amplifier cladding-pumped at 976 nm with output power in excess of 100 W, 8961, 1-6(2014).

[12] Changsheng YANG, Xianchao GUAN, Qilai ZHAO et al. 15 W high OSNR kHz-linewidth linearly-polarized all-fiber single-frequency MOPA at 1.6 μm. Optics Express, 26, 12863-12869(2018).

[13] Chunlei YU, Meng WANG, Suya FENG et al. Research progress on ytterbium-doped large mode area photonic crystal fibers. Laser & Optoelectronics Progress, 56, 170602(2019).

[14] Ruofan ZHANG, Wenrui ZHANG, Xuejiao ZHANG et al. Research status and development trend of high earth orbit satellite laser relay links. Laser & Optoelectronics Progress, 58, 0500001(2021).

[15] C R GILES, E DESURVIRE. Modeling erbium-doped fiber amplifiers. Journal of Lightwave Technology, 9, 271-283(1991).

[16] M M KHUDYAKOV, A S LOBANOV, D S LIPATOV et al. Single-mode large-mode-area Er-Yb fibers with core based on phosphorosilicate glass highly doped with fluorine. Laser Physics Letters, 16, 025105(2019).

[17] M KARASEK. Optimum design of Er3+/Yb3+ co-doped fibers for large-signal high-pump-power applications. IEEE Journal of Quantum Electronics, 33, 1699-1705(2002).

[18] Andi ZHANG, Yanrong ZHANG, Tao LI. Application of variable domain fuzzy PID control in semiconductor laser temperature control system. Acta Optica Sinica, 41, 1214003(2021).