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Visible Light Communication for Connected Vehicles: How to Achieve the Omnidirectional Coverage?

Hossien B. Eldeeb, Sadiq M. Sait, Murat Uysal

2021IEEE Access47 citationsDOIOpen Access PDF

Abstract

Visible light communication (VLC) is based on the idea of modulating the light intensity of LEDs to transmit information and enables the dual use of exterior automotive and road side infrastructure lighting for both illumination and communication purposes. To position VLC as a strong candidate for vehicular connectivity, it is essential to realize multi-directional reception in various deployment scenarios supporting both vehicle-to-vehicle (V2V) and infrastructure-to-vehicle (I2V) links. In this paper, we investigate the performance of a vehicular VLC system in different road types (i.e., multi-lane, curved roads), intersections (i.e., T-shaped, Y-shaped intersections) and traffic scenarios (i.e., cruising in the same or different lanes, lane change etc.). We conduct a channel modeling study based on non-sequential ray tracing to quantify the capability of receiving signals in different cases. Our results reveal that deployment of nine photodetectors with carefully determined locations on the vehicle is enough to create the required quasi-omni-directional coverage for both V2V connectivity (in front and back directions) and I2V connectivity.

Topics & Concepts

Visible light communicationComputer scienceSoftware deploymentOmnidirectional antennaChannel (broadcasting)Ray tracing (physics)WirelessLED lampReal-time computingComputer networkLight-emitting diodeTelecommunicationsAntenna (radio)Electrical engineeringEngineeringQuantum mechanicsOperating systemPhysicsOptical Wireless Communication TechnologiesImpact of Light on Environment and HealthSmart Parking Systems Research
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