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使用Teegraph改进车辆网络认证:一种基于哈希图的高效方法。

Improving Vehicular Network Authentication with Teegraph: A Hashgraph-Based Efficiency Approach.

作者信息

Cádiz Rubén Juárez, Nicolas-Sans Ruben, Tamámes José Fernández

机构信息

School of Engineering, Science, and Technology, UNIE Universidad, Calle Arapiles, 14, 28015 Madrid, Spain.

出版信息

Sensors (Basel). 2025 Aug 7;25(15):4856. doi: 10.3390/s25154856.

DOI:10.3390/s25154856
PMID:40808020
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12349144/
Abstract

Vehicular ad hoc networks (VANETs) are a critical aspect of intelligent transportation systems, improving safety and comfort for drivers. These networks enhance the driving experience by offering timely information vital for safety and comfort. Yet, VANETs come with their own set of challenges concerning security, privacy, and design reliability. Traditionally, vehicle authentication occurs every time a vehicle enters the domain of the roadside unit (RSU). In our study, we suggest that authentication should take place only when a vehicle has not covered a set distance, increasing system efficiency. The rise of the Internet of Things (IoT) has seen an upsurge in the use of IoT devices across various fields, including smart cities, healthcare, and vehicular IoT. These devices, while gathering environmental data and networking, often face reliability issues without a trusted intermediary. Our study delves deep into implementing Teegraph in VANETs to enhance authentication. Given the integral role of VANETs in Intelligent Transportation Systems and their inherent challenges, we turn to Hashgraph-an alternative to blockchain. Hashgraph offers a decentralized, secure, and trustworthy database. We introduce an efficient authentication system, which triggers only when a vehicle has not traversed a set distance, optimizing system efficiency. Moreover, we shed light on the indispensable role Hashgraph can occupy in the rapidly expanding IoT landscape. Lastly, we present Teegraph, a novel Hashgraph-based technology, as a superior alternative to blockchain, ensuring a streamlined, scalable authentication solution. Our approach leverages the logical key hierarchy (LKH) and packet update keys to ensure data privacy and integrity in vehicular networks.

摘要

车载自组织网络(VANETs)是智能交通系统的关键组成部分,可提高驾驶员的安全性和舒适度。这些网络通过提供对安全和舒适至关重要的及时信息来提升驾驶体验。然而,VANETs在安全、隐私和设计可靠性方面存在一系列自身的挑战。传统上,每当车辆进入路边单元(RSU)的领域时就会进行车辆认证。在我们的研究中,我们建议仅在车辆未行驶设定距离时进行认证,以提高系统效率。物联网(IoT)的兴起见证了物联网设备在包括智能城市、医疗保健和车联网等各个领域的使用激增。这些设备在收集环境数据和联网时,如果没有可信的中介,往往会面临可靠性问题。我们的研究深入探讨了在VANETs中实施Teegraph以增强认证。鉴于VANETs在智能交通系统中的不可或缺作用及其固有挑战,我们转向Hashgraph——区块链的一种替代方案。Hashgraph提供了一个去中心化、安全且值得信赖的数据库。我们引入了一种高效的认证系统,该系统仅在车辆未行驶设定距离时触发,从而优化系统效率。此外,我们阐明了Hashgraph在迅速扩展的物联网格局中可以发挥的不可或缺作用。最后,我们介绍了Teegraph,一种基于Hashgraph的新颖技术,作为区块链的一种更优替代方案,确保了一个简化、可扩展的认证解决方案。我们的方法利用逻辑密钥层次结构(LKH)和数据包更新密钥来确保车辆网络中的数据隐私和完整性。

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Integrated IoT-Based Secure and Efficient Key Management Framework Using Hashgraphs for Autonomous Vehicles to Ensure Road Safety.基于物联网的集成安全高效密钥管理框架,使用哈希图用于自动驾驶汽车,以确保道路安全。
Sensors (Basel). 2022 Mar 25;22(7):2529. doi: 10.3390/s22072529.
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A Secure Pseudonym-Based Conditional Privacy-Preservation Authentication Scheme in Vehicular Ad Hoc Networks.
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