Using Intermittent Chaotic Clocks to Secure Cryptographic Chips

IF 1.7 4区计算机科学 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Embedded Systems Letters Pub Date : 2024-10-07 DOI:10.1109/LES.2024.3472709

Abdollah Masoud Darya;Sohaib Majzoub;Ali A. El-Moursy;Mohamed Wed Eladham;Khalid Javeed;Ahmed S. Elwakil

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Abstract

This letter proposes using intermittent chaotic clocks, generated from chaotic maps, to drive cryptographic chips running the advanced encryption standard as a countermeasure against correlation power analysis (CPA) attacks. Five different chaotic maps, namely, the logistic map, the Bernoulli shift map, the Henon map, the tent map, and the Ikeda map, are used in this letter to generate chaotic clocks. The performance of these chaotic clocks is evaluated in terms of timing overhead and the resilience of the driven chip against CPA attacks. All proposed chaotic clocking schemes successfully protect the driven chip against attacks, with the clocks produced by the optimized Ikeda, Henon, and logistic maps achieving the lowest-timing overhead. These optimized maps, due to their intermittent chaotic behavior, exhibit lower-timing overhead compared to previous work. Notably, the chaotic clock generated by the optimized Ikeda map approaches the theoretical limit of timing overhead, i.e., half the execution time of a reference periodic clock.

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使用间歇混沌时钟保护密码芯片

这封信建议使用由混沌映射生成的间歇性混沌时钟来驱动运行高级加密标准的加密芯片，作为对抗相关功率分析（CPA）攻击的对策。这封信中使用了五种不同的混沌地图，即logistic地图、伯努利位移地图、Henon地图、tent地图和Ikeda地图来生成混沌时钟。这些混沌时钟的性能是根据时序开销和驱动芯片对CPA攻击的弹性来评估的。所有提出的混沌时钟方案都成功地保护了驱动芯片免受攻击，由优化的Ikeda， Henon和logistic映射产生的时钟实现了最低的时序开销。这些优化的地图，由于其间歇性混沌行为，与以前的工作相比，显示出更低的时间开销。值得注意的是，优化后的池田映射生成的混沌时钟接近于定时开销的理论极限，即参考周期时钟执行时间的一半。

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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来源期刊

IEEE Embedded Systems Letters Engineering-Control and Systems Engineering

CiteScore

3.30

自引率

0.00%

发文量

期刊介绍： The IEEE Embedded Systems Letters (ESL), provides a forum for rapid dissemination of latest technical advances in embedded systems and related areas in embedded software. The emphasis is on models, methods, and tools that ensure secure, correct, efficient and robust design of embedded systems and their applications.