Transmitter diversity and OAM incorporated 40 Gbps free space optical system

Journal of Optical Communications Pub Date : 2024-05-14 DOI:10.1515/joc-2024-0017

Somdeep Singh, Preeti Singh, Pardeep Kaur

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Abstract

The present research evaluates optical angular momentum’s (OAM) performance in challenging atmospheric conditions and emphasizes its significance in free space optical (FSO) communication systems. It has been demonstrated that implementing the transmitter diversity (TD) technique effectively suppresses inter-channel interference, improving system performance as a whole. The best option among the studied encodings is found to be the combination of non-return-to-zero (NRZ) and carrier suppressed RZ (CSRZ), which performs better in a variety of weather scenarios and covers a wide FSO range from 72 m to 1450 m. Proposed system offered distance enhancement of 81.25 % under clear sky, 16.66 % under light rain, 10.22 % under moderate rain, 3.4 % under heavy rain, 10 % under light haze, 4 % under moderate haze, 4.44 % under heavy haze, 12.5 % under light fog, 4 % under moderate fog, 7.8 % under heavy fog, 5.8 % under light dust, 7.6 % under medium dust and 12.5 % under heavy dust as compared to existing workIn particular, during bad weather, this research offers significant insights into the design and optimisation of high-speed FSO systems.

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包含 40 Gbps 自由空间光学系统的发射机分集和 OAM

本研究评估了光角动量（OAM）在具有挑战性的大气条件下的性能，并强调了其在自由空间光学（FSO）通信系统中的重要性。研究表明，采用发射机分集（TD）技术可有效抑制信道间干扰，从而从整体上提高系统性能。研究发现，非归零（NRZ）和载波抑制 RZ（CSRZ）编码的组合是所研究编码的最佳选择，在各种天气情况下都有较好的表现，并覆盖了从 72 米到 1450 米的宽 FSO 范围。在晴朗天气下，拟议系统的距离增强率为 81.25%；在小雨天气下为 16.66%；在中雨天气下为 10.22%；在大雨天气下为 3.4%；在轻度雾霾天气下为 10%；在中度雾霾天气下为 4%；在重度雾霾天气下为 4.44%；在轻度雾霾天气下为 12.5%；在中度雾霾天气下为 4%；在重度雾霾天气下为 7.特别是在恶劣天气下，这项研究为高速 FSO 系统的设计和优化提供了重要启示。

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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