在可变大气条件下利用波分复用器减轻自由空间光学中的衰减效应

Q3 Engineering
Dhrumi Chaudhari, Sandeep Rajput
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引用次数: 0

摘要

这项研究深入探讨了自由空间光学(FSO)通信系统中波分复用(WDM)的优化问题,旨在增强系统抵御大气干扰的能力。FSO 通信以其在未授权频段的高带宽能力而著称,但经常会遇到与天气有关的信号衰减所导致的可靠性问题。本研究采用一种新颖的波分复用-FSO 方法,通过使用切换技术来扩展工作范围,从而确保通信的一致性和可靠性。在这种情况下,引入先进的切换和分叉机制至关重要,可促进动态信号路由和光放大器的战略布局,以抵消天气波动和地理挑战对信号完整性的影响。该系统可支持 25 Gbps 的数据传输速率,满足了需要高带宽的应用需求。通过在各种大气条件下基于 Q 因子和误码率的严格性能评估,证明了 WDM-FSO 系统的有效性。研究结果通过图表进行了详细说明,使人们对系统的性能有了全面的了解。这项研究为无线光通信领域做出了重大贡献,它提出了一种优化的波分复用-FSO 系统,该系统能够克服与天气有关的障碍,尤其是在天气条件经常变化的地方,这标志着在建立更可靠的 FSO 通信网络方面向前迈进了一步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mitigating attenuation effects in free-space optics using WDM under variable atmospheric conditions
This research delves into the optimization of wavelength division multiplexing (WDM) within free space optical (FSO) communication systems, aiming to enhance the system’s resilience against atmospheric disruptions. FSO communication, known for its high bandwidth capabilities in unlicensed frequency bands, often encounters reliability issues due to weather-related signal degradation. By integrating a novel WDM-FSO approach, this study seeks to extend the operational range by using switching technique, thereby ensuring consistent and reliable communication. The introduction of a sophisticated switching and fork mechanism is pivotal in this context, facilitating dynamic signal routing and the strategic placement of optical amplifiers to counteract the impact of weather fluctuations and geographical challenges on signal integrity. This system, engineered to support a data transmission rate of 25 Gbps, caters to the needs of applications requiring high bandwidth. Through rigorous performance evaluation based on the Q-factor and BER under various atmospheric conditions, the effectiveness of the WDM-FSO system is demonstrated. The findings are detailed through graphs and tables, providing a comprehensive understanding of the system’s performance. This study makes a significant contribution to the field of wireless optical communication by presenting an optimized WDM-FSO system capable of overcoming weather-related obstacles especially at places where weather conditions are changed very frequently, marking a step forward in establishing more reliable FSO communication networks.
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来源期刊
Journal of Optical Communications
Journal of Optical Communications Engineering-Electrical and Electronic Engineering
CiteScore
2.90
自引率
0.00%
发文量
86
期刊介绍: This is the journal for all scientists working in optical communications. Journal of Optical Communications was the first international publication covering all fields of optical communications with guided waves. It is the aim of the journal to serve all scientists engaged in optical communications as a comprehensive journal tailored to their needs and as a forum for their publications. The journal focuses on the main fields in optical communications
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