Improvement and Cryptanalysis of a Physically Unclonable Functions Based Authentication Scheme for Smart Grids

Safkhani, Masoumeh; Bagheri, Nasour; Ali, Saqib; Malik, Mazhar Hussain; Ahmed, Omed Hassan; Hosseinzadeh, Mehdi; Mosavi, Amir

doi:10.3390/math11010048

Cited by 5 publications

(1 citation statement)

References 32 publications

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“…Following the assumption of the former study [2] and similar to [67][68][69], Dolev-Yao (DY) [70], for an active adversary, and Canetti and Krawczyk (CK) [71] adversary models for a stronger attacker that has more capabilities than in the DY model. All attackers are active and capable of listening in, stopping, altering, or beginning message delivery.…”

Section: System Modelmentioning

confidence: 99%

Toward Designing a Secure Authentication Protocol for IoT Environments

et al. 2023

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Authentication protocol is a critical part of any application to manage the access control in many applications. A former research recently proposed a lightweight authentication scheme to transmit data in an IoT subsystem securely. Although the designers presented the first security analysis of the proposed protocol, that protocol has not been independently analyzed by third-party researchers, to the best of our knowledge. On the other hand, it is generally agreed that no cryptosystem should be used in a practical application unless its security has been verified through security analysis by third parties extensively, which is addressed in this paper. Although it is an efficient protocol by design compared to other related schemes, our security analysis identifies the non-ideal properties of this protocol. More specifically, we show that this protocol does not provide perfect forward secrecy. In addition, we show that it is vulnerable to an insider attacker, and an active insider adversary can successfully recover the shared keys between the protocol’s entities. In addition, such an adversary can impersonate the remote server to the user and vice versa. Next, the adversary can trace the target user using the extracted information. Finally, we redesign the protocol such that the enhanced protocol can withstand all the aforementioned attacks. The overhead of the proposed protocol compared to its predecessor is only 15.5% in terms of computational cost.

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Section: System Modelmentioning

confidence: 99%

Toward Designing a Secure Authentication Protocol for IoT Environments

et al. 2023

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Lightweight Batch Authentication Protocol for Bus-NB-IoT Hierarchical Network in Smart Grid Using Physically Unclonable Function

Liu

Sun

Zheng

et al. 2023

2023 IEEE 9th Intl Conference on Big Data Security on Cloud (BigDataSecurity), IEEE Intl Conference on High Performance and Sma

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PUF-Based Robust and Anonymous Authentication and Key Establishment Scheme for V2G Networks

Yu,

Park

2024

IEEE Internet Things J.

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Vehicle-to-grid (V2G) improves flexibility, reliability, and efficiency and ensures effective charging services by enabling two-way communication along with two-way electricity transmission between the power grid and electric vehicle (EV). However, V2G networks are fragile to lethal security threats because an attacker may try to compromise and control the communication participants at any time. Recently, Sureshkumar et al. presented a robust and lightweight authentication key establishment (AKE) for secure V2G networks to provide essential security properties. However, we prove that their scheme suffered from various security threats and lacked essential security properties. To protect against physical security attacks, a promising solution is the use of physical unclonable function (PUF) technology and many AKE schemes have been designed for V2G networks. However, these schemes are still fragile to machine learning (ML)-based modeling attacks as well as existing security threats. Thus, we design a physical unclonable function (PUF)-based robust and anonymous AKE scheme for V2G networks, called R2AKEV2G to resist ML-based modeling attacks. We prove the security of R2AKEV2G by performing formal security analyses. Moreover, we perform a network simulator (NS) 3 implementation in compliance with IEEE 802.11 to prove its feasibility and verify that R2AKE-V2G is suitable for practical V2G networks. Consequently, R2AKE-V2G supports better security features and functionalities attributes and also guarantees superior costs with regard to communication and computation as compared to existing relevant schemes.

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Improvement and Cryptanalysis of a Physically Unclonable Functions Based Authentication Scheme for Smart Grids

Cited by 5 publications

References 32 publications

Toward Designing a Secure Authentication Protocol for IoT Environments

Toward Designing a Secure Authentication Protocol for IoT Environments

Lightweight Batch Authentication Protocol for Bus-NB-IoT Hierarchical Network in Smart Grid Using Physically Unclonable Function

PUF-Based Robust and Anonymous Authentication and Key Establishment Scheme for V2G Networks

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