Implementation of forward error correction for improved performance of free space optical communication channel in adverse atmospheric conditions

Q3 Physics and Astronomy
S.L. Sathiya Narayanan, B.C. Dhanush Devappa, Kalyani Pawar, Shreyas Jain, Appala Venkata Ramana Murthy
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引用次数: 0

Abstract

The tremendous speed and security that Free Space Optical Communication (FSOC) technology provides have led to its rapid expansion. This opens up a plethora of possibilities for terrestrial communication with small ranges of up to a few kilometers, such as multi-campus and building-to-building communication. However, the ever-varying nature of atmospheric channels poses a major challenge degrading the optical signal strength. Several constituents of atmospheric channels like fog, dust, smoke, rain, and wind turbulence will influence the performance of an FSOC channel. In this paper, we present a system model focusing on adverse atmospheric channels, primarily by replicating varying fog conditions. Additionally, we showcase the successful real-time implementation of diverse forward error correction (FEC) codes in adverse atmospheric conditions, specifically varying levels of fog, using a dedicated test bed. Our experiments demonstrate the capability to recover erroneous data up to 50% Bit Error Rates (BER). Furthermore, we delve into the selection of suitable FEC codes tailored to different fog conditions, aiming to optimize time efficiency with the encoded bitrate.

实施前向纠错,提高自由空间光通信信道在不利大气条件下的性能
自由空间光通信(FSOC)技术提供的巨大速度和安全性使其迅速发展。这为小范围(最多几公里)地面通信提供了大量可能性,如多校园和楼宇间通信。然而,大气信道不断变化的性质对降低光信号强度构成了重大挑战。雾、尘、烟、雨和风湍流等大气信道的多种成分都会影响 FSOC 信道的性能。在本文中,我们主要通过复制不同的雾条件,提出了一个以不利大气信道为重点的系统模型。此外,我们还展示了在不利的大气条件下,特别是在不同程度的雾中,利用专用测试平台成功地实时实施了多种前向纠错(FEC)编码。我们的实验证明,我们有能力恢复误码率高达 50%的错误数据。此外,我们还深入研究了如何根据不同的雾气条件选择合适的 FEC 编码,以优化编码比特率的时间效率。
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
Results in Optics
Results in Optics Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
2.50
自引率
0.00%
发文量
115
审稿时长
71 days
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