Evaluating the effects of material reflectivity and atmospheric attenuation on photonic radar performance in free space optical channels

Q3 Engineering Journal of Optical Communications Pub Date : 2023-07-31 DOI:10.1515/joc-2023-0176
Abhishek Sharma, J. Malhotra
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引用次数: 2

Abstract

Abstract The automotive industry is on the verge of embracing autonomous vehicles in the near future. In the pursuit of developing self-driving cars, photonic radars have emerged as a reliable sensor technology. These radars operate based on free space optical channels, but they are vulnerable to various atmospheric challenges. In this research, the objective is to examine the effect of material reflectivity on target recognition by utilizing photonic radar under various atmospheric conditions within free space optical channels. We explore four distinct scenarios representing targets with reflectivity ranging from 90 % to 20 %. The findings of this study indicate a decrease in received signal strength as reflectivity decreases across all analysed atmospheric conditions. The key findings include successful detection of stationary targets at a 1000-m range, the impact of target reflectivity on echo signal intensity and resolution, and the system’s effective performance in detecting targets even in dense fog conditions of up to 50 dB/km and are further validated through theoretical analysis.
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自由空间光通道中材料反射率和大气衰减对光子雷达性能影响的评估
摘要在不久的将来,汽车行业即将拥抱自动驾驶汽车。在开发自动驾驶汽车的过程中,光子雷达已经成为一种可靠的传感器技术。这些雷达基于自由空间光学信道运行,但它们容易受到各种大气挑战的影响。本研究的目的是在自由空间光通道内,利用光子雷达在各种大气条件下检测材料反射率对目标识别的影响。我们探索了四种不同的场景,表示反射率在90之间的目标 % 至20 %. 这项研究的结果表明,在所有分析的大气条件下,随着反射率的降低,接收信号强度会降低。关键发现包括在1000米范围内成功探测到静止目标,目标反射率对回波信号强度和分辨率的影响,以及该系统在高达50米的浓雾条件下探测目标的有效性能 dB/km,并通过理论分析得到进一步验证。
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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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