Side-Channel Attacks on Triple Modular Redundancy Schemes

2021 IEEE 30th Asian Test Symposium (ATS) Pub Date : 2021-04-09 DOI:10.1109/ATS52891.2021.00026

Felipe Almeida, L. Aksoy, J. Raik, S. Pagliarini

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Abstract

Triple Modular Redundancy (TMR) is a well-known fault tolerance technique for avoiding errors in the Integrated Circuits (ICs) and it has been used in a wide range of applications. The TMR technique employs three instances of circuits realizing concurrently the same functionality whose outputs are compared through a majority voter. On the other hand, Side-Channel Attacks (SCAs) are powerful techniques to extract secret information from ICs based on the data collected from security critical operations. Over the years, the interplay between security and reliability is poorly studied. In this paper, we explore the performance of SCAs on the well-known Advanced Encryption Standard (AES) and its different realizations using the TMR technique. In this work, three implementations of the AES design under the TMR scheme are used and an SCA, which can collect power dissipation data from the physical netlist through simulations, is developed. The experimental results show that the TMR technique can increase the computation time of SCAs and more importantly, the use of functionally equivalent, but physically and structurally different instances in the TMR scheme can make it impossible for SCAs to discover the secret key.

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三模冗余方案的侧信道攻击

三模冗余(TMR)是一种众所周知的容错技术，用于避免集成电路(ic)中的错误，并得到了广泛的应用。TMR技术采用三个电路实例并发实现相同的功能，其输出通过多数投票人进行比较。另一方面，侧信道攻击(sca)是基于从安全关键操作中收集的数据从ic中提取秘密信息的强大技术。多年来，安全性和可靠性之间的相互作用研究很少。在本文中，我们探讨了sca在著名的高级加密标准(AES)上的性能及其使用TMR技术的不同实现。在本文中，采用了三种TMR方案下的AES设计实现，并通过仿真开发了一个能够从物理网表中收集功耗数据的SCA。实验结果表明，TMR技术可以增加sca的计算时间，更重要的是，在TMR方案中使用功能等效但物理和结构不同的实例可以使sca无法发现密钥。

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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2021 IEEE 30th Asian Test Symposium (ATS)

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