Resilient and Privacy-Preserving Threshold Vehicular Public Key Infrastructure (VPKI)

TL;DR

This paper introduces a threshold-based VPKI architecture using elliptic curve cryptography to enhance resilience, scalability, and privacy in vehicular networks, addressing key limitations of current systems.

Contribution

It proposes a novel threshold VPKI scheme that distributes trust among multiple CAs, improves resilience, and reduces revocation latency, advancing secure vehicular communication.

Findings

Enhanced resilience against single point-of-failure

Reduced CRL size and distribution latency

Improved scalability and privacy preservation

Abstract

Vehicular Public Key Infrastructure (VPKI) plays a vital role in ensuring secure and privacy-preserving communication in vehicular ad hoc networks (VANETs). However, current VPKI architectures face significant challenges in terms of scalability, resilience, and privacy preservation. This paper proposes a novel threshold-based VPKI architecture to overcome these limitations. Leveraging a Schnorr threshold signature scheme based on elliptic curve cryptography, the proposed architecture eliminates the reliance on individual certificate authorities (CAs) and distributes trust among multiple CAs in a threshold certificate signing approach. This enhances resilience and mitigates the single point-of-failure vulnerability. The architecture also addresses sybil-based misbehaviors through a time-restrictive pseudonym design that eliminates multiple simultaneous use of pseudonyms. Furthermore, the scheme reduces the size and latency of Certificate Revocation List (CRL) distribution by clustering multiple CAs in a threshold setting and adopting a region-specific CRL. The paper presents detailed analysis of the security, privacy and performance benefits of the proposed architecture. Results from the performance evaluation shows the improved resiliency, reduced handover rates, and better scalability potential of the proposed threshold-based VPKI architecture compared to existing techniques. The proposed threshold-based VPKI holds great promise in ensuring secure and privacy-preserving communication in VANETs, paving the way for safer and more efficient vehicular networks.