BLOCOVID: A blockchain-based COVID-19 digital vaccination certificate verification system

2022 International Conference on Engineering and Emerging Technologies (ICEET) Pub Date : 2022-10-27 DOI:10.1109/ICEET56468.2022.10007366

P. Agbedanu, F. U. Bawah, V. Akoto-Adjepong, N. S. Awarayi, Isaac Kofi Nti, S. Boateng, P. Nimbe, O. Nyarko-Boateng

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引用次数: 1

Abstract

The global impact of the COVID-19 pandemic has been felt in diverse ways. Although the death rate in Africa has not been as devastating as predicted by the World Health Organization (WHO), its economic and social impact has been fully felt by the African continent. As the world goes through the vaccination process to achieve herd immunity, Africa has not only faced problems like the inability to produce and procure vaccines, but some countries in the west are doubting the authenticity of the vaccination process and even vaccine certificates coming from various countries on the continent. The approach of using centralized systems to validate COVID-19 vaccine certificates makes these systems susceptible to Denial of Service (DoS), modification, and Man-in-the-Middle (MiTM) attacks. To curb this problem, we proposed a blockchain-based digital COVID-19 vaccination certificate verification system called BLOCOVID. The proposed system uses the decentralized approach of distributed ledgers to ensure that vaccine certificates are secured, immutable, and verifiable. Our proposed system stores vaccine serial numbers and their corresponding certificates as hash values. These hash values are stored on the blockchain network as transaction values. The authenticity of a vaccine certificate is determined by the availability of the hash values of the certificate and its corresponding vaccine serial number on the blockchain network. The proposed system was simulated using the BlockSim simulator. To begin with, the simulation results show that the proposed system can ensure system availability, thereby minimizing DoS attacks. Secondly, the proposed system can ensure the integrity of vaccine certificates by allowing third parties to verify the authenticity of these certificates. The simulation results show that even with 10240 nodes, the average transaction time was 137.2ms, with a total transaction rate of 9911.034 transactions per second.

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BLOCOVID:基于区块链的COVID-19数字疫苗接种证书验证系统

2019冠状病毒病大流行对全球的影响是多方面的。虽然非洲的死亡率并不像世界卫生组织(卫生组织)所预测的那样具有毁灭性，但非洲大陆已充分感受到其经济和社会影响。在全世界都在经历疫苗接种过程以实现群体免疫的过程中，非洲不仅面临着无法生产和采购疫苗等问题，而且西方一些国家对疫苗接种过程的真实性甚至来自非洲大陆各国的疫苗证书表示怀疑。使用集中式系统验证COVID-19疫苗证书的方法使这些系统容易受到拒绝服务(DoS)、修改和中间人(MiTM)攻击。为了解决这个问题，我们提出了一个基于区块链的数字COVID-19疫苗接种证书验证系统，称为BLOCOVID。该系统使用分布式账本的去中心化方法来确保疫苗证书的安全性、不可变性和可验证性。我们提出的系统将疫苗序列号及其对应的证书存储为哈希值。这些哈希值作为交易值存储在区块链网络上。疫苗证书的真实性取决于证书的哈希值及其对应的疫苗序列号在区块链网络上的可用性。利用BlockSim模拟器对该系统进行了仿真。首先，仿真结果表明，该系统能够保证系统的可用性，从而最大限度地减少DoS攻击。其次，该系统允许第三方验证疫苗证书的真实性，从而保证疫苗证书的完整性。仿真结果表明，即使在10240个节点下，平均事务时间为137.2ms，总事务率为9911.034个事务/秒。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 International Conference on Engineering and Emerging Technologies (ICEET)

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