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    Journals >Advanced Photonics Nexus >Volume 2 >Issue 6 >Page 065001 > Article
    • Advanced Photonics Nexus
    • Vol. 2, Issue 6, 065001 (2023)
    High-speed free-space optical communication using standard fiber communication components without optical amplification
    Hua-Ying Liu1、†,*, Yao Zhang1, Xiaoyi Liu1, Luyi Sun1, Pengfei Fan1, Xiaohui Tian1, Dong Pan2, Mo Yuan3, Zhijun Yin3, Guilu Long2, Shi-Ning Zhu1, and Zhenda Xie1、*
    Author Affiliations
  • 1Nanjing University, College of Engineering and Applied Sciences, and Collaborative Innovation Center of Advanced Microstructures, School of Electronic Science and Engineering, School of Physics, National Laboratory of Solid State Microstructures, Nanjing, China
  • 2Beijing Academy of Quantum Information Sciences, Beijing, China
  • 3Xin Lian Technology Co., Ltd., Huzhou, China
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    DOI: 10.1117/1.APN.2.6.065001 Cite this Article Set citation alerts
    Hua-Ying Liu, Yao Zhang, Xiaoyi Liu, Luyi Sun, Pengfei Fan, Xiaohui Tian, Dong Pan, Mo Yuan, Zhijun Yin, Guilu Long, Shi-Ning Zhu, Zhenda Xie. High-speed free-space optical communication using standard fiber communication components without optical amplification[J]. Advanced Photonics Nexus, 2023, 2(6): 065001 Copy Citation Text show less
    References

    [1] W.-S. Tsai et al. A 20-m/40-Gb/s 1550-nm DFB LD-based FSO link. IEEE Photonics J., 7, 1-7(2015).

    [2] H. Henniger, O. Wilfert. An introduction to free-space optical communications. Radioengineering, 19, 203-213(2010).

    [3] M. A. Khalighi, M. Uysal. Survey on free space optical communication: a communication theory perspective. IEEE Commun. Surv. Tut., 16, 2231-2258(2014).

    [4] B. Mukherjee, H. Kaushal et al. Free-space optical channel models. Free Space Optical Communication, 41-89(2017).

    [5] M. Toyoshima. Recent trends in space laser communications for small satellites and constellations. J. Lightwave Technol., 39, 693-699(2020).

    [6] A. B. Raj, A. K. Majumder. Historical perspective of free space optical communications: from the early dates to today’s developments. IET Commun., 13, 2405-2419(2019).

    [7] H. Kaushal, G. Kaddoum. Optical communication in space: challenges and mitigation techniques. IEEE Commun. Surv. Tut., 19, 57-96(2016).

    [8] X.-M. Li, Z.-Z. Li, X.-M. Li. Airborne space laser communication system and experiments. Proc. SPIE, 9795, 97950G(2015).

    [9] X.-M. Li et al. Airborne laser communication technology and flight test. Proc. SPIE, 9795, 97950E(2015).

    [10] A. Jahid, M. H. Alsharif, T. J. Hall. A contemporary survey on free space optical communication: potentials, technical challenges, recent advances and research direction. J. Netw. Comput. Appl., 200, 103311(2022).

    [11] E. Farooq, A. Sahu, S. K. Gupta. Survey on FSO communication system—limitations and enhancement techniques, 255-264(2018).

    [12] M. Tornatore et al. A survey on network resiliency methodologies against weather-based disruptions(2016).

    [13] B. S. Robinson et al. The NASA lunar laser communication demonstration—successful high-rate laser communications to and from the moon, 1685(2014).

    [14] F. Moll et al. Demonstration of high-rate laser communications from a fast airborne platform. IEEE J. Sel. Areas Commun., 33, 1985-1995(2015).

    [15] T. S. Rose et al. Optical communications downlink from a 1.5 U CubeSat: OCSD program. Proc. SPIE, 11180, 111800J(2019).

    [16] C.-X. Tu et al. A lower size, weight acquisition and tracking system for airborne quantum communication. IEEE Photonics J., 14, 1-8(2022).

    [17] M. Karimi, M. Nasiri-Kenari. Free space optical communications via optical amplify-and-forward relaying. J. Lightwave Technol., 29, 242-248(2011).

    [18] S. Kumar. Enhancing performance of coherent optical OFDM FSO communication link using cascaded EDFA. Wireless Personal Commun., 120, 1109-1123(2021).

    [19] S. H. Alnajjar, A. A. Noori, A. A. Moosa. Enhancement of FSO communications links under complex environment. Photonic Sens., 7, 113-122(2017).

    [20] M. Singh. Mitigating the effects of fog attenuation in FSO communication link using multiple transceivers and EDFA. J. Opt. Commun., 38, 169-174(2017).

    [21] open-source tool iperf3.

    [22] L. Jingzhen. Handbook of Optics(2010).

    [23] D. Pan et al. Experimental free-space quantum secure direct communication and its security analysis. Photonics Res., 8, 1522-1531(2020).

    [24] D. Pan, X.-T. Song, G.-L. Long. Free-space quantum secure direct communication: basics, progress, and outlook. Adv. Devices Instrum., 4, 0004(2023).

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    Hua-Ying Liu, Yao Zhang, Xiaoyi Liu, Luyi Sun, Pengfei Fan, Xiaohui Tian, Dong Pan, Mo Yuan, Zhijun Yin, Guilu Long, Shi-Ning Zhu, Zhenda Xie. High-speed free-space optical communication using standard fiber communication components without optical amplification[J]. Advanced Photonics Nexus, 2023, 2(6): 065001
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