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一种用于车载自组织网络的安全高效的基于区块链的联邦Q学习模型。

A secure and efficient blockchain enabled federated Q-learning model for vehicular Ad-hoc networks.

作者信息

Ahmed Huda A, Jasim Hend Muslim, Gatea Ali Noori, Al-Asadi Ali Amjed Ali, Al-Asadi Hamid Ali Abed

机构信息

College of Computer Science and Information Technology, University of Basrah, Basrah, Iraq.

Department of Computer Science, College of Education for Pure Sciences, University of Basrah, Basrah, Iraq.

出版信息

Sci Rep. 2024 Dec 28;14(1):31235. doi: 10.1038/s41598-024-82585-3.

DOI:10.1038/s41598-024-82585-3
PMID:39732861
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11682394/
Abstract

Vehicular Ad-hoc Networks (VANETs) are growing into more desirable targets for malicious individuals due to the quick rise in the number of automated vehicles around the roadside. Secure data transfer is necessary for VANETs to preserve the integrity of the entire network. Federated learning (FL) is often suggested as a safe technique for exchanging data among VANETs, however, its capacity to protect private information is constrained. This research proposes an extra level of security to Federated Q-learning by merging Blockchain technology with VANETs. Initially, traffic data is encrypted utilizing the Extended Elliptic Curve Cryptography (EX-ECC) technique to enhance the security of data. Then, the Federated Q-learning model trains the data and ensures higher privacy protection. Moreover, interplanetary file system (IPFS) technology allows Blockchain storage to improve the security of VANETs information. Additionally, the validation process of the proposed Blockchain framework is performed by utilizing a Delegated Practical Byzantine Fault Tolerance (DPBFT) based consensus algorithm. The proposed approach to federated Q-learning offered by Blockchain technology has the potential to develop VANET safety and performance. Comprehensive simulation tests are performed with several assessment criteria considered for number of vehicles 100, Throughput (102465.8 KB/s), Communication overhead (360.57 Mb), Average Latency (864.425 ms), Communication Time (19.51 s), Encryption time (0.98 ms), Decryption time (1.97 ms), Consensus delay (50 ms) and Validation delay (1.68 ms), respectively. As a result, the proposed approach performs significantly better than the existing approaches.

摘要

由于路边自动驾驶车辆数量的迅速增加,车载自组织网络(VANETs)正日益成为恶意个体更青睐的目标。安全的数据传输对于VANETs维护整个网络的完整性至关重要。联邦学习(FL)常被认为是一种在VANETs之间交换数据的安全技术,然而,其保护隐私信息的能力受到限制。本研究通过将区块链技术与VANETs相结合,为联邦Q学习提出了额外的安全级别。首先,利用扩展椭圆曲线密码学(EX-ECC)技术对交通数据进行加密,以增强数据的安全性。然后,联邦Q学习模型对数据进行训练,并确保更高的隐私保护。此外,星际文件系统(IPFS)技术允许区块链存储,以提高VANETs信息的安全性。此外,所提出的区块链框架的验证过程是通过使用基于委托实用拜占庭容错(DPBFT)的共识算法来执行的。区块链技术提供的联邦Q学习方法有潜力提升VANETs的安全性和性能。针对车辆数量100、吞吐量(102465.8 KB/s)、通信开销(360.57 Mb)、平均延迟(864.425 ms)、通信时间(19.51 s)、加密时间(0.98 ms)、解密时间(1.97 ms)、共识延迟(50 ms)和验证延迟(1.68 ms)等多个评估标准进行了全面的模拟测试。结果表明,所提出的方法比现有方法表现得显著更好。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fb05/11682394/6509ed18a8ec/41598_2024_82585_Fig14_HTML.jpg
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本文引用的文献

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Multi-objectives reinforcement federated learning blockchain enabled Internet of things and Fog-Cloud infrastructure for transport data.基于区块链的多目标强化联邦学习物联网及用于传输数据的雾云基础设施。
Heliyon. 2023 Nov 2;9(11):e21639. doi: 10.1016/j.heliyon.2023.e21639. eCollection 2023 Nov.