Post-quantum cryptography Algorithm's standardization and performance analysis

IF 2.3 Q2 COMPUTER SCIENCE, THEORY & METHODS Array Pub Date : 2022-09-01 DOI:10.1016/j.array.2022.100242
Manish Kumar
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Abstract

-Quantum computer is no longer a hypothetical idea. It is the world's most important technology and there is a race among countries to get supremacy in quantum technology. It is the technology that will reduce the computing time from years to hours or even minutes. The power of quantum computing will be a great support for the scientific community. However, it raises serious threats to cybersecurity. Theoretically, all the cryptography algorithms are vulnerable to attack. The practical quantum computers, when available with millions of qubits capacity, will be able to break nearly all modern public-key cryptographic systems. Before the quantum computers arrive with sufficient ‘qubit’ capacity, we must be ready with quantum-safe cryptographic algorithms, tools, techniques, and deployment strategies to protect the ICT infrastructure. This paper discusses in detail the global effort for the design, development, and standardization of various quantum-safe cryptography algorithms along with the performance analysis of some of the potential quantum-safe algorithms. Most quantum-safe algorithms need more CPU cycles, higher runtime memory, and a large key size. The objective of the paper is to analyze the feasibility of the various quantum-safe cryptography algorithms.

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后量子密码算法的标准化与性能分析
量子计算机不再是一个假想的想法。这是世界上最重要的技术,各国之间正在进行一场争夺量子技术霸权的竞赛。这项技术将把计算时间从几年缩短到几小时甚至几分钟。量子计算的力量将为科学界提供巨大的支持。然而,它对网络安全构成了严重威胁。从理论上讲,所有的加密算法都容易受到攻击。实用的量子计算机,当拥有数百万量子位容量时,将能够破解几乎所有现代公钥加密系统。在量子计算机具备足够的“量子比特”容量之前,我们必须准备好量子安全的加密算法、工具、技术和部署策略,以保护ICT基础设施。本文详细讨论了各种量子安全加密算法的设计、开发和标准化的全球努力,并对一些潜在的量子安全算法进行了性能分析。大多数量子安全算法需要更多的CPU周期、更高的运行时内存和更大的密钥大小。本文的目的是分析各种量子安全密码算法的可行性。
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来源期刊
Array
Array Computer Science-General Computer Science
CiteScore
4.40
自引率
0.00%
发文量
93
审稿时长
45 days
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