探索不同大气条件下的 FSO 链路性能,利用极化准漫反射发射机优化 5G 通信

Nirav S. Desai, Sandeep J. Rajput
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引用次数: 0

摘要

自由空间光学(FSO)通信是一项创新技术,具有数据传输速率高、可快速扩展、成本效益高、安全性高以及可实现 Gbps 数据传输的综合容量接入技术等优点,因此在众多应用领域大有可为。FSO 通信依赖地球大气层作为介质,而大气层会带来干扰,这推动了旨在提高该技术性能的空间分集技术的发展。我们提出的系统采用带叉的极化准扩散系统作为空间分集方案,无需多个发射器。我们开发了一个模型,将两种模拟设计整合在一起,以获得最佳结果。所提出的模型在雨、雾、霾等各种大气湍流条件下都表现出卓越的性能,显示出极高的最大品质因数、更高的接收功率和更好的误码率 (BER)。最后,我们获取、分析并广泛讨论了模拟结果,以全面了解所提模型的潜在优势。我们的模拟结果表明,与现有模型相比,最大品质因数提高了 23%,接收功率提高了 34%,误码率降低了 31%。这些结果凸显了拟议模型在 FSO 通信系统中的潜在优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exploring FSO link performance in varied atmospheric conditions to optimize 5G communication with a polarized quasi-diffuse transmitter
Free space optical (FSO) communication is an innovative technology that holds immense promise for numerous applications thanks to its high data transmission rates, rapid scalability, cost-effectiveness, superior security, and comprehensive capacity access techniques for Gbps data transmission. FSO communication relies on the Earth’s atmosphere as the medium, which introduces atmospheric disturbances that have driven the development of spatial diversity techniques aimed at enhancing the technology’s performance. Our proposed system employs a polarized quasi-diffused system with a fork as a spatial diversity scheme, which eliminates the need for multiple transmitters. We have developed a model that integrates both simulation designs to achieve optimal results. The proposed model has demonstrated excellent performance under various atmospheric turbulences, including rain, fog, and haze, exhibiting a very high maximum quality factor, improved received power, and better bit error rate (BER). Finally, we have obtained, analyzed, and extensively discussed the simulation results to provide a comprehensive understanding of the proposed model’s potential benefits. Our simulations show a maximum quality factor of 23 compared to existing models in much better, a 34 % increase in received power, and a 31 % decrease in BER compared to existing models. These results highlight the potential benefits of the proposed model for FSO communication systems.
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