Blockchain Based Privacy and Security Across Cloud in Electric Vehicle Application for Sustainable Development in Industry, Innovation and Infrastructure

Abstract

Purpose: In this paper we utilise electric vehicle-based cloud edge (EVCE) computing, it is possible to integrate vehicle contexts in a seamless manner. With the increasing use of electric vehicles (EVs) in V2X, this is likely to become a trend. When it comes to information and energy exchanges, a hybrid cloud/edge computing system with EVs as a potential resource infrastructure presents considerable security challenges. In order to find context-aware vehicular applications, the viewpoints of information and energy interactions are taken into consideration. The use of distributed consensus has resulted in the creation of blockchain-inspired energy and data coins, which use the frequency of data contributions and the amount of energy contributions to demonstrate the proof of work for each coin. When it comes to protecting vehicle interactions, the industry, innovation, and infrastructure sectors of Envision2030 are confronted with a number of different security alternatives. Design/Methodology/Approach: The EVCE computing for mobile cloud architecture to the electric vehicle acting as the edges across the network. The unutilised energy resources, and communication and computational resources of EVs are pooled together and used for other purposes. Mobile cloudlets for electric vehicles are created using VANETs and other interconnected services that gets connected together. When EVs are parked for extended periods of time in different locations, they form a cooperative network of services. Incorporating flexible connected EVs into traditional cloud infrastructures enables contact with remote service providers, local area networks (LANs), as well as other organisations, while operating in the cloud computing mode. Findings/Result: The primary purpose of a blockchain application is to maintain a record of all of the transactions that have been made by the various members of the network. After the submitted transactions have been confirmed and arranged, a block is formed, and the outcomes of the transactions are put on the blockchain as transaction results. Originality/Value: When it comes to transactions, HLF three-stage revolutionary design, dubbed execute-order-validate, is reliant on the preceding steps of the transaction to function properly. Because the actual throughput is close to 100%, a 100 TPS transmit rate is achievable and sustainable Paper Type: Experimental Research