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Efficiency and Reliability of Avalanche Consensus Protocol in Vehicular Communication Networks | IEEE Conference Publication | IEEE Xplore
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Efficiency and Reliability of Avalanche Consensus Protocol in Vehicular Communication Networks

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Saeed Ullah; Zaib Ullah; Abdullah Waqas
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Abstract:

In vehicular communication networks, centralized systems face significant security challenges, including privacy preservation, secure authentication, threats from comprom...Show More

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Abstract:

In vehicular communication networks, centralized systems face significant security challenges, including privacy preservation, secure authentication, threats from compromised authorities, latency, and throughput. We propose a blockchain-based system that decentralizes control, enhances throughput, and optimizes latency. By leveraging the Avalanche consensus protocol, our solution assures efficient, secure, and robust communication within vehicular networks, mitigating risks associated with centralized control. Our proposed system achieves a substantial throughput, with the Practical Byzantine Fault Tolerance (PBFT) protocol registering 12.8 transactions per second (TPS), and the Avalanche protocol demonstrates an impressive 1007 TPS for 100 validators. Regarding the delay, PBFT experiences 6.61 seconds, whereas Avalanche protocol achieves a remarkably low delay of just one millisecond, both with 100 validators. These findings highlight the superiority of our proposed system in terms of low latency, and enhanced transaction throughput, essential for future vehicular communication systems.
Published in: 2024 19th Conference on Computer Science and Intelligence Systems (FedCSIS)
Date of Conference: 08-11 September 2024
Date Added to IEEE Xplore: 04 November 2024
ISBN Information:
DOI: 10.15439/2024F3909
Conference Location: Belgrade, Serbia

Funding Agency:

References is not available for this document.
Contents

I. Introduction

In recent years, blockchain technology has emerged as a transformative solution for enhancing security and decentralization across various domains. Originally conceived for cryptocurrencies, blockchain’s immutable and distributed ledger system offers robust security features, making it an attractive option for applications requiring secure and transparent data handling. The effective use of blockchain technology plays a crucial role in building smart cities [1]. Additionally, blockchain technology is vital in monitoring systems that assist elderly and impaired patients in adhering to their medication regimens at home. By leveraging blockchain, these systems ensure that all patient-related activities are securely logged and verified, providing a reliable and secure framework for patient care management [2].

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