A Secure Pseudonym-Based Conditional Privacy-Preservation Authentication Scheme in Vehicular Ad Hoc Networks

Al-Shareeda, Mahmood A.; Anbar, Mohammed; Manickam, Selvakumar; Hasbullah, Iznan H.

doi:10.3390/s22051696

Cited by 35 publications

(19 citation statements)

References 36 publications

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“…These properties contrast with encryption-based, which assumes an eavesdropper has limited computational power to solve complex mathematical problems quickly [21]. Consequently, leveraging PLS with cryptographic techniques such as authentication and key generation is a powerful approach to secure confidential communications in future wireless (URLLC) [33], vehicular ad hoc networks (VANETs) [34], and sensor communications [35].…”

Section: Physical Layer Security For Xg Networkmentioning

confidence: 99%

Interplay between Physical Layer Security and Blockchain Technology for 5G and Beyond: A Comprehensive Survey

Ghourab¹,

Jaafar²,

Bariah³

et al. 2023

Preprint

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Fifth-generation and beyond (5G and xG) wireless networks are envisioned to meet the requirements of various vertical applications that require higher traffic throughput, ultra-massive connectivity, extremely low latency, and high quality of service. Disruptive technologies, such as massive multiple-input multiple-output, millimeter wave, and multiple access are being deployed to meet these requirements. However, the deployment of these technologies poses several challenges, including the lack of network transparency, management decentralization, and reliability. In addition, the heterogeneity of these networks raises security concerns, particularly, confidentiality, privacy, and trustworthiness. Typically, networks rely on encryption techniques at higher layers to ensure security and privacy. However, due to the emergence of novel computing paradigms, such as quantum computing, traditional security approaches are no longer sufficient to protect over-the-air communications. Therefore, 5G/xG networks must consider smarter and more efficient security techniques to operate seamlessly and efficiently. Within this context, physical layer security (PLS) and blockchain represent promising solutions to complement existing methods. By exploiting the characteristics of wireless links, PLS can enhance the security of wireless communications, while blockchain can guarantee the decentralization, integrity, and trustworthiness of networks. Motivated by these technological advancements, this paper provides an in-depth review of the existing literature on PLS and blockchain. Then, for the first time, we present a framework for the integration of PLS with blockchain in 5G/xG systems. We begin by providing a thorough discussion about the potential of PLS and blockchain for 5G/xG systems. Next, we present our vision of a cross-layer architecture that leverages both PLS and blockchain in 5G/xG networks. Finally, we identify related challenges and open issues and shed light on future research directions.

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Section: Physical Layer Security For Xg Networkmentioning

confidence: 99%

Interplay between Physical Layer Security and Blockchain Technology for 5G and Beyond: A Comprehensive Survey

Ghourab¹,

Jaafar²,

Bariah³

et al. 2023

Preprint

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“…The vehicular ad hoc networks (VANETs) aim to provide drivers and passengers with smarter, safer, and more entertainment services. In the coming fifth-generation (5G) era, the participating vehicle in the vehicular network is investigated to be installed with an on-board unit (OBU) for vehicle-to-everything (V2X) communication [1][2][3]. Therefore, the vehicle can exchange messages with others and the outside world.…”

Section: Introductionmentioning

confidence: 99%

CM-CPPA: Chaotic Map-Based Conditional Privacy-Preserving Authentication Scheme in 5G-Enabled Vehicular Networks

Al-Shareeda

Manickam

Mohammed

et al. 2022

Sensors

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The security and privacy concerns in vehicular communication are often faced with schemes depending on either elliptic curve (EC) or bilinear pair (BP) cryptographies. However, the operations used by BP and EC are time-consuming and more complicated. None of the previous studies fittingly tackled the efficient performance of signing messages and verifying signatures. Therefore, a chaotic map-based conditional privacy-preserving authentication (CM-CPPA) scheme is proposed to provide communication security in 5G-enabled vehicular networks in this paper. The proposed CM-CPPA scheme employs a Chebyshev polynomial mapping operation and a hash function based on a chaotic map to sign and verify messages. Furthermore, by using the AVISPA simulator for security analysis, the results of the proposed CM-CPPA scheme are good and safe against general attacks. Since EC and BP operations do not employ the proposed CM-CPPA scheme, their performance evaluation in terms of overhead such as computation and communication outperforms other most recent related schemes. Ultimately, the proposed CM-CPPA scheme decreases the overhead of computation of verifying the signatures and signing the messages by 24.2% and 62.52%, respectively. Whilst, the proposed CM-CPPA scheme decreases the overhead of communication of the format tuple by 57.69%.

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“…The 5G network has the characteristics of a wide covered area increased by 1000 times, battery life reduced by five times, and high bandwidth improved by 10 Gbps compared to the fourth generation (4G). It brings many new challenges for mobile ad hoc networks (MANET), especially for vehicular networks [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Chebyshev Polynomial-Based Scheme for Resisting Side-Channel Attacks in 5G-Enabled Vehicular Networks

et al. 2022

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The privacy and security vulnerabilities in fifth-generation (5G)-enabled vehicular networks are often required to cope with schemes based on either bilinear pair cryptography (BPC) or elliptic curve cryptography (ECC). Nevertheless, these schemes suffer from massively inefficient performance related to signing and verifying messages in areas of the high-density traffic stream. Meanwhile, adversaries could launch side-channel attacks to obtain sensitive data protected in a tamper-proof device (TPD) to destroy the system. This paper proposes a Chebyshev polynomial-based scheme for resisting side-channel attacks in 5G-enabled vehicular networks. Our work could achieve both important properties of the Chebyshev polynomial in terms of chaotic and semi-group. Our work consists of five phases: system initialization, enrollment, signing, verification, and pseudonym renew. Moreover, to resist side-channel attacks, our work renews periodically and frequently the vehicle’s information in the TPD. Security analysis shows that our work archives the privacy (pseudonym identity and unlikability) and security (authentication, integrity, and traceability) in 5G-enabled vehicular networks. Finally, our work does not employ the BPC or the ECC; its efficiency performance outperforms other existing recent works, making it suitable for use in vehicular networks.

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A Secure Pseudonym-Based Conditional Privacy-Preservation Authentication Scheme in Vehicular Ad Hoc Networks

Cited by 35 publications

References 36 publications

Interplay between Physical Layer Security and Blockchain Technology for 5G and Beyond: A Comprehensive Survey

Interplay between Physical Layer Security and Blockchain Technology for 5G and Beyond: A Comprehensive Survey

CM-CPPA: Chaotic Map-Based Conditional Privacy-Preserving Authentication Scheme in 5G-Enabled Vehicular Networks

Chebyshev Polynomial-Based Scheme for Resisting Side-Channel Attacks in 5G-Enabled Vehicular Networks

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