学术文献库

This paper studies the physical layer security (PLS) of a vehicular network employing reconfigurable intelligent surfaces (RISs). RIS technologies are emerging as an important paradigm for the realisation of next-generation smart radio environments, where large numbers of small, low-cost and passive elements, reflect the incident signal with an adjustable phase shift without requiring a dedicated energy source. Inspired by the promising potential of RIS-based transmission, we investigate the PLS of two vehicular network system models: One with vehicle-to-vehicle communication with the source employing a RIS-based access point, and the other is in the form of a vehicular adhoc network (VANET), with a RIS-based relay deployed on a building; both models assume the presence of an eavesdropper. The performance of the proposed systems are evaluated in terms of the average secrecy capacity (ASC) and the secrecy outage probability (SOP). We present accurate analytical expressions for the two performance metrics and study the impact of various system parameters on the overall performance of the two considered system configurations. Monte-Carlo simulations are provided throughout to validate the results. The results show that performance of the system in terms of the ASC and SOP is affected by the location of the RIS-relay as well as the number of RIS cells. Moreover, upto an order magnitude gain could be achieved within certain regions when the number of RIS cells are doubled, clearly indicating the benefit of employing a RIS configuration.