A security framework with strong non-repudiation and privacy in VANETs
CCNC'09 Proceedings of the 6th IEEE Conference on Consumer Communications and Networking Conference
An efficient anonymous authentication mechanism for delay tolerant networks
Computers and Electrical Engineering
Distributed certificate and application architecture for VANETs
MILCOM'09 Proceedings of the 28th IEEE conference on Military communications
Efficient CRL search in vehicular network PKIS
Proceedings of the 6th ACM workshop on Digital identity management
Multi-objective optimal combination queries
DEXA'11 Proceedings of the 22nd international conference on Database and expert systems applications - Volume Part I
On batch verification with group testing for vehicular communications
Wireless Networks
Privacy preserving neighborhood awareness in vehicular ad hoc networks
Proceedings of the 7th ACM symposium on QoS and security for wireless and mobile networks
Public key distribution scheme for delay tolerant networks based on two-channel cryptography
Journal of Network and Computer Applications
Efficient and multi-level privacy-preserving communication protocol for VANET
Computers and Electrical Engineering
Unified security architecture and protocols using third party identity in V2V and V2I networks
Wireless Communications & Mobile Computing
Efficient privacy-preserving authentication protocol for vehicular communications with trustworthy
Security and Communication Networks
Improvements on an authentication scheme for vehicular sensor networks
Expert Systems with Applications: An International Journal
Mobile Networks and Applications
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Vehicular communication networking is a promising approach to facilitating road safety, traffic management, and infotainment dissemination for drivers and passengers. One of the ultimate goals in the design of such networking is to resist various malicious abuses and security attacks. In this article we first review the current standardization process, which covers the methods of providing security services and preserving driver privacy for wireless access in vehicular environments (WAVE) applications. We then address two fundamental issues, certificate revocation and conditional privacy preservation, for making the standards practical. In addition, a suite of novel security mechanisms are introduced for achieving secure certificate revocation and conditional privacy preservation, which are considered among the most challenging design objectives in vehicular ad hoc networks.