Abstract
The use of visible light communications technology in communication-based vehicle applications is gaining more and more interest as the research community is constantly overcoming challenge after challenge. In this context, this article addresses the issues associated with the use of Visible Light Communications (VLC) technology in Vehicle-to-Vehicle (V2V) communications, while focusing on two crucial issues. On the one hand, it aims to investigate the achievable communication distance in V2V applications while addressing the least favorable case, namely the one when a standard vehicle rear lighting system is used as a VLC emitter. On the other hand, this article investigates another highly unfavorable use case scenario, i.e., the case when two vehicles are located on adjacent lanes, rather than on the same lane. In order to evaluate the compatibility of the VLC technology with the usage in inter-vehicle communication, a VLC prototype is intensively evaluated in outdoor conditions. The experimental results show a record V2V VLC distance of 75 m, while providing a Bit Error Ratio (BER) of 10−7–10−6. The results also show that the VLC technology is able to provide V2V connectivity even in a situation where the vehicles are located on adjacent lanes, without a major impact on the link performances. Nevertheless, this situation generates an initial no-coverage zone, which is determined by the VLC receiver reception angle, whereas in some cases, vehicle misalignment can generate a BER increase that can go up to two orders of magnitude.
Highlights
Due to the unique properties of visible light, the Visible Light Communications (VLC) technology has been found to be suitable for underwater communications [2], whereas due to its lack of electromagnetic interferences, it is envisioned as a solution in potentially dangerous locations such as chemical plants, nuclear plants or in underground mines [3], where the usage of Radio-Frequency (RF)-based communications could be unsafe
The analysis provided by [58] is interesting, it should be mentioned that the analyzed scenario is based on a Lambertian radiation pattern and not on a real vehicle light distribution pattern, which can have a great impact on the final result, as demonstrated in [59] and in [60]
This article addressed some of the issues associated with the exploitation of the VLC technology in V2V applications, focusing on an experimental-centered approach
Summary
The wide distribution of LED light sources and the numerous benefits of VLC technology have attracted attention from numerous researchers and a wide range of applications have been identified. Due to the unique properties of visible light, the VLC technology has been found to be suitable for underwater communications [2], whereas due to its lack of electromagnetic interferences, it is envisioned as a solution in potentially dangerous locations such as chemical plants, nuclear plants or in underground mines [3], where the usage of Radio-Frequency (RF)-based communications could be unsafe. The ubiquitous character of LED light sources enables the VLC technology to be suitable in Internet of Things (IoT) applications [4,5]. Due to its ability to provide low latency, energy-efficient and cost-effective connections, the VLC technology has been found to be appropriate for industrial use, including in the Industry 4.0 domain [6]
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