Enhancing the Performance of Free-Space-Optics Transmission System Using Mode-Division-Multiplexing of Hermite–Gaussian and Laguerre–Gaussian Beams

IF 0.9 Q4 TELECOMMUNICATIONS

Internet Technology Letters Pub Date : 2025-02-27 DOI:10.1002/itl2.649

K. C. Ramya, M. R. Thiyagupriyadharsan, V. Sivasankaran, Leta Tesfaye Jule, A. Sampathkumar

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Abstract

Emergence of 5G networks has led to rising demand for high-speed data networks. Free-space optics (FSO) play a pivotal role in providing high-speed large-capacity secure communication links required for fronthaul/backhaul services in 5G communication networks. Conventional FSO links are based on wavelength division multiplexing which make the system costlier, bulky and spectral-inefficient. In this work, a mode-division-multiplexing-(MDM)-enabled-FSO transmission system is proposed and evaluated to provide cost-effective, high-speed, and spectral-efficient data transmission. Hybrid Hermite–Gaussian (HG) and Laguerre–Gaussian (LG) modes are integrated to enhance the performance of the system. Four independent 10 Gbps data signals are transmitted along 2-distinct HG beams $({HG}_{10} and {HG}_{11})$ and 2-distinct LG beams $({LG}_{00} and {LG}_{11})$ over the free space channel. The performance evaluated is reported for clear climate and also for adverse rain climate where Quality factor metrics, Bit Error Rate Metrics, and eye diagram representation of the received signals are discussed. The proposed work reports definitive 40 Gbps along 11 km for clear climate followed by 1100–2300 m for varying levels of rain climate.

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利用厄米-高斯和拉盖尔-高斯光束分模复用提高自由空间光传输系统的性能

5G网络的出现导致了对高速数据网络的需求不断上升。自由空间光学（FSO）在提供5G通信网络前传/回程业务所需的高速大容量安全通信链路方面发挥着关键作用。传统的FSO链路是基于波分复用的，这使得系统更昂贵，体积更大，频谱效率更低。在这项工作中，提出并评估了一种支持模分复用（MDM）的fso传输系统，以提供经济高效、高速和频谱高效的数据传输。为了提高系统的性能，采用了Hermite-Gaussian （HG）和Laguerre-Gaussian （LG）混合模式。四个独立的10gbps数据信号沿两个不同的HG波束HG 10和HG 11和两个不同的LG波束传输LG 00和LG 11在自由空间频道。在晴朗的气候和恶劣的降雨气候下，对性能进行了评估，其中讨论了质量因子指标、误码率指标和接收信号的眼图表示。拟议的工作报告明确指出，在气候晴朗的情况下，沿着11公里的道路传输速率为40 Gbps，然后在不同程度的降雨气候下，沿着1100-2300米传输速率为40 Gbps。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Internet Technology Letters

CiteScore

3.10

自引率

0.00%

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