[1] KAUSHAL H, KADDOUM G. Underwater optical wireless communication[J]. IEEE Access, 4, 1518-1547(2016).

[2] ZENG Z, FU S, ZHANG H et al. A survey of underwater optical wireless communications[J]. IEEE Communications Surveys & Tutorials, 19, 204-238(2017).

[3] WU Qiong, WANG Bo, WANG Tao et al. Analysis of underwater wireless optical transmission characteristics based on Monte Carlo method[J]. Acta Photonica Sinica, 50, 0406002(2021).

[4] CHENG En, YUAN Fei, SU Wei et al. Research on technology of underwater acoustic communication[J]. Journal of Xiamen University (Natural Science), 50, 271-275(2011).

[5] JIANG Hongyan. Key performance of the underwater wireless optical communication over turbulent channels[D](2021).

[6] WANG Fei, YANG Yi, DUAN Zuoliang et al. Characteristic analysis of underwater laser signal transmission channel based on visible light[J]. Optical Communication Technology, 40, 26-28(2016).

[7] BAI J, CAO C, YANG Y et al. Peak-to-average power ratio reduction for DCO-OFDM underwater optical wireless communication system based on an interleaving technique[J]. Optical Engineering, 57, 086110(2018).

[8] FU Yuqing, DUAN Qi, ZHOU Lin. Performance of underwater wireless optical communication system in Gamma Gamma strong oceanic turbulence with pointing error[J]. Infrared and Laser Engineering, 49, 110-117(2020).

[9] HE Fengtao, LI Jiaqi, ZHANG Jianlei et al. Performance analysis of wavelength diversity wireless optical communication system in ocean turbulence[J]. Infrared and Laser Engineering, 50, 1-10(2021).

[10] CAO Minghua, WU Xin, YANG Shunxin et al. BER performance of Faster-than-Nyquist communications under Log-normal turbulence channel[J]. Optics and Precision Engineering, 28, 465-473(2020).

[11] ZHANG J, KOU L, YANG Y et al. Monte-Carlo-based optical wireless underwater channel modeling with oceanic turbulence[J]. Optics Communications, 475, 126214(2020).

[12] JAMALI M V, KHORRAMSHAHI P, TASHAKORI A et al. Statistical distribution of intensity fluctuations for underwater wireless optical channels in the presence of air bubbles[C](2016).

[13] OUBEI H M, ZEDINI E, ELAFANDY R T et al. Simple statistical channel model for weak temperature-induced turbulence in underwater wireless optical communication systems[J]. Optics Letters, 42, 2455-2458(2017).

[14] OUBEI H M, ZEDINI E, ELAFANDY R T et al. Efficient Weibull channel model for salinity induced turbulent underwater wireless optical communications[C](2017).

[15] ZEDINI E, OUBEI H M, KAMMOUN A et al. Unified statistical channel model for turbulence-induced fading in underwater wireless optical communication systems[J]. IEEE Transactions on Communications, 67, 2893-2907(2019).

[16] RAMAVATH P N, UDUPI S A, KRISHNAN P. High-speed and reliable underwater wireless optical communication system using multiple-input multiple-output and channel coding techniques for IoUT applications[J]. Optics Communications, 461, 125229(2020).

[17] CANER G M, BAYKAL Y, ATE Y. Performance analysis of M-ary pulse position modulation in strong oceanic turbulence[J]. Optics Communications, 427, 573-577(2018).

[18] HE Fengtao, DU Ying, ZHANG Jianlei et al. Bit error rate of pulse position modulation wireless optical communication in gamma-gamma oceanic anisotropic turbulence[J]. Acta Physica Sinica, 68, 236-244(2019).

[19] ZOU Z, WANG P, CHEN W et al. Average capacity of a UWOC system with partially coherent gaussian beams propagating in weak oceanic turbulence[J]. Journal of the Optical Society of America A, 36, 1463(2019).

[20] XIE Shuhao. Research and implementation of high speed OQPSK digital demodulation synchronization technology[D](2018).

[21] ZHAO Qinghua. Study on OQPSK modulation and demodulation performance[D](2010).

[22] ZHU S, CHEN X, LIU X et al. Recent progress in and perspectives of underwater wireless optical communication[J]. Progress in Quantum Electronics, 73, 100274(2020).

[23] JAMALI M V, MIRANI A, PARSAY A et al. Statistical studies of fading in underwater wireless optical channels in the presence of air bubble, temperature, and salinity random variations[J]. IEEE Transactions on Communications, 66, 4706-4723(2018).

[24] ROBERT C, CASELLA G. Monte Carlo statistical methods[M]. Springer Science & Business Media(2013).

[25] WU Tong, JI Xiaoling, LUO Yuju. Characteristic parameters of adaptive optical imaging system in oceanic turbulence[J]. Acta Physica Sinica, 67, 156-163(2018).

[26] ZEDINI E, SOURY H, ALOUINI M S. Dual-Hop FSO transmission systems over gamma-gamma turbulence with pointing errors[J]. IEEE Transactions on Wireless Communications, 16, 784-796(2017).