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    Journals >Acta Photonica Sinica >Volume 53 >Issue 3 >Page 0301002 > Article
    • Acta Photonica Sinica
    • Vol. 53, Issue 3, 0301002 (2024)
    Bit Error Rate Performance Study of UWOC System Based on Multiple Degenerate Composite Channels
    Jianlei ZHANG1, Pengwei ZHANG1,*, Yunzhou ZHU2, Yuxin TIAN1..., Jieyu LI1, Yi YANG1 and Fengtao HE1|Show fewer author(s)
    Author Affiliations
  • 1School of Electronic Engineering, Xi'an University of Posts and Telecommunications, Xi'an 710072, China
  • 2Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi'an 710119, China
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    DOI: 10.3788/gzxb20245303.0301002 Cite this Article
    Jianlei ZHANG, Pengwei ZHANG, Yunzhou ZHU, Yuxin TIAN, Jieyu LI, Yi YANG, Fengtao HE. Bit Error Rate Performance Study of UWOC System Based on Multiple Degenerate Composite Channels[J]. Acta Photonica Sinica, 2024, 53(3): 0301002 Copy Citation Text show less
    References

    [1] Z ZENG, S FU, H ZHANG et al. A survey of underwater optical wireless communications. IEEE Communications Surveys & Tutorials, 19, 204-238(2016).

    [2] W LIU, Z XU, L YANG. SIMO detection schemes for underwater optical wireless communication under turbulence. Photonics Research, 3, 48-53(2015).

    [3] F HANSON, S RADIC. High bandwidth underwater optical communication. Applied Optics, 47, 277-283(2008).

    [4] N CHI, Y ZHOU, Y WEI et al. Visible light communication in 6G: Advances, challenges, and prospects. IEEE Vehicular Technology Magazine, 15, 93-102(2020).

    [5] M LE-TRAN, S KIM. Performance analysis of multi-hop underwater wireless optical communication systems over exponential-generalized gamma turbulence channels. IEEE Transactions on Vehicular Technology, 71, 6214-6227(2022).

    [6] S JARUWATANADILOK. Underwater wireless optical communication channel modeling and performance evaluation using vector radiative transfer theory. IEEE Journal on Selected Areas in Communications, 26, 1620-1627(2008).

    [7] C GABRIEL, M A KHALIGHI, S BOURENNANE et al. Channel modeling for underwater optical communication, 833-837(2011).

    [8] C GABRIEL, M A KHALIGHI, S BOURENNANE et al. Monte-Carlo-based channel characterization for underwater optical communication systems. Journal of Optical Communications and Networking, 5, 1-12(2013).

    [9] L C ANDREWS, R L PHILLIPS, C Y HOPEN. Laser beam scintillation with applications(2001).

    [10] H GERÇEKCIOĞLU. Bit error rate of focused Gaussian beams in weak oceanic turbulence. Journal of the Optical Society of America A, 31, 1963-1968(2014).

    [11] X YI, Z LI, Z LIU. Underwater optical communication performance for laser beam propagation through weak oceanic turbulence. Applied Optics, 54, 1273-1278(2015).

    [12] M V JAMALI, P KHORRAMSHAHI, A TASHAKORI et al. Statistical distribution of intensity fluctuations for underwater wireless optical channels in the presence of air bubbles, 1-6(2016).

    [13] Y ATA, K KIASALEH. Analysis of optical wireless communication links in turbulent underwater channels with wide range of water parameters. IEEE Transactions on Vehicular Technology, 72, 6363-6374(2023).

    [14] D C BLANCHARD, A H WOODCOCK. Bubble formation and modification in the sea and its meteorological significance. Tellus, 9, 145-158(1957).

    [15] X ZHANG, M LEWIS, B JOHNSON. Influence of bubbles on scattering of light in the ocean. Applied Optics, 37, 6525-6536(1998).

    [16] R M HAGEM, D V THIEL, S G O'KEEFE et al. The effect of air bubbles on an underwater optical communications system for wireless sensor network applications. Microwave and Optical Technology Letters, 54, 729-732(2012).

    [17] D K WOOLF. Encyclopedia of ocean sciences. USA: Academic(2001).

    [18] D M FARMER, D D LEMON. The influence of bubbles on ambient noise in the ocean at high wind speeds. Journal of Physical Oceanography, 14, 1762-1778(1984).

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

    [20] M I MISHCHENKO, P YANG. Far-field Lorenz-Mie scattering in an absorbing host medium: theoretical formalism and FORTRAN program. Journal of Quantitative Spectroscopy and Radiative Transfer, 205, 241-252(2018).

    [21] W J WISCOMBE. Improved Mie scattering algorithms. Applied Optics, 19, 1505-1509(1980).

    [22] Y WU, L SHI, Y GONG et al. Simultaneous measurement of bubble size and growth with phase critical angle scattering. Optics and Lasers in Engineering, 136, 106302(2021).

    [23] G CHUA, M CHITRE, G B DEANE. Long-lived bubbles and their impact on underwater acoustic communication. IEEE Journal of Oceanic Engineering, 46, 1008-1023(2020).

    [24] J WU. Bubble flux and marine aerosol spectra under various wind velocities. Journal of Geophysical Research: Oceans, 97, 2327-2333(1992).

    [25] B D JOHNSON, R C COOKE. Generation of stabilized microbubbles in seawater. Science, 213, 209-211(1981).

    [26] A HUANG, L TAO. Monte Carlo based channel characteristics for underwater optical wireless communications. IEICE Transactions on Communications, 100, 612-618(2017).

    [27] A MOREL, S MARITORENA. Bio-optical properties of oceanic waters: a reappraisal. Journal of Geophysical Research: Oceans, 106, 7163-7180(2001).

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

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

    [30] M A AL-HABASH, L C ANDREWS, R L PHILLIPS. Mathematical model for the irradiance probability density function of a laser beam propagating through turbulent media. Optical Engineering, 40, 1554-1562(2001).

    [31] R BARRIOS, F DIOS. Exponentiated Weibull model for the irradiance probability density function of a laser beam propagating through atmospheric turbulence. Optics & Laser Technology, 45, 13-20(2013).

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

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

    [34] V S ADAMCHIK, O I MARICHEV. The algorithm for calculating integrals of hypergeometric type functions and its realization in REDUCE system, 212-224(1990).

    [35] A P PRUDNIKOV, O I MARICHEV. Integrals and series: special functions(1986).

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    Jianlei ZHANG, Pengwei ZHANG, Yunzhou ZHU, Yuxin TIAN, Jieyu LI, Yi YANG, Fengtao HE. Bit Error Rate Performance Study of UWOC System Based on Multiple Degenerate Composite Channels[J]. Acta Photonica Sinica, 2024, 53(3): 0301002
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