Visible to the public Physical Layer Continuous Authentication for Wireless Mesh Networks: An Experimental Study

TitlePhysical Layer Continuous Authentication for Wireless Mesh Networks: An Experimental Study
Publication TypeConference Paper
Year of Publication2022
AuthorsIlli, Elmehdi, Pandey, Anshul, Bariah, Lina, Singh, Govind, Giacalone, Jean-Pierre, Muhaidat, Sami
Conference Name2022 IEEE International Mediterranean Conference on Communications and Networking (MeditCom)
Date Publishedsep
Keywordsauthentication, composability, Mesh networks, Metrics, Physical layer, programmable logic arrays, pubcrawl, resilience, Resiliency, Scattering, Wireless communication, wireless mesh networks
AbstractThis paper investigates the robustness of the received signal strength (RSS)-based physical layer authentication (PLA) for wireless mesh networks, through experimental results. Specifically, we develop a secure wireless mesh networking framework and apply the RSS-based PLA scheme, with the aim to perform continuous authentication. The mesh setup comprises three Raspberry-PI4 computing nodes (acting as Alice, Bob, and Eve) and a server. The server role is to perform the initial authentication when a new node joins the mesh network. After that, the legitimate nodes in the mesh network perform continuous authentication, by leveraging the RSS feature of wireless signals. In particular, Bob tries to authenticate Alice in the presence of Eve. The performance of the presented framework is quantified through extensive experimental results in an outdoor environment, where various nodes' positions, relative distances, and pedestrian speeds scenarios are considered. The obtained results demonstrate the robustness of the underlying model, where an authentication rate of 99% for the static case can be achieved. Meanwhile, at the pedestrian speed, the authentication rate can drop to 85%. On the other hand, the detection rate improves when the distance between the legitimate and wiretap links is large (exceeds 20 meters) or when Alice and Eve are moving in different mobility patterns.
DOI10.1109/MeditCom55741.2022.9928604
Citation Keyilli_physical_2022