LAT-UP: Exposing Layout-Level Analog Hardware Trojans Using Contactless Optical Probing

2023 IEEE Computer Society Annual Symposium on VLSI (ISVLSI) Pub Date : 2023-06-20 DOI:10.1109/ISVLSI59464.2023.10238545

Sajjad Parvin, Mehran Goli, Thilo Krachenfels, Shahin Tajik, Jean-Pierre Seifert, Frank Sill, R. Drechsler

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Abstract

The insertion of a Hardware Trojan (HT) into a chip after the in-house layout design is outsourced to a chip manufacturer for fabrication is a major concern, especially for mission-critical applications. While several HT detection methods have been developed based on side-channel analysis and physical measurements to overcome this problem, there exist stealthy analog HTs, i.e., capacitive and dopant-level HTs, which have negligible or even zero overhead on the chip. Thus, these stealthy HTs cannot be detected using the aforementioned methods. In this work, we propose a novel analytical approach to detect these Layout-level Analog Trojans (LAT). Our proposed method uses an extension of Optical Probing (OP) for LAT detection, namely, the Laser Logic State Imaging (LLSI) technique. In principle, to detect LATs using LLSI, we only need the golden design and not a golden chip, which is not typically available. As we take advantage of LLSI to detect HTs, our approach is non-invasive, less costly, and scalable to larger designs. We report experimental results on a malicious RISC-V to demonstrate the effectiveness of our approach in detecting LATs.

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latup:使用非接触式光学探测暴露布局级模拟硬件木马

在内部布局设计外包给芯片制造商制造后，将硬件木马(HT)插入芯片是一个主要问题，特别是对于任务关键型应用程序。虽然已经开发了几种基于侧信道分析和物理测量的高温超导检测方法来克服这个问题，但仍然存在隐形模拟高温超导，即电容级和掺杂级高温超导，它们在芯片上的开销可以忽略不计，甚至为零。因此，使用上述方法无法检测到这些隐形ht。在这项工作中，我们提出了一种新的分析方法来检测这些布局级模拟木马(LAT)。我们提出的方法使用光学探测(OP)的扩展进行LAT检测，即激光逻辑状态成像(LLSI)技术。原则上，要使用LLSI检测lat，我们只需要黄金设计，而不需要黄金芯片，这通常是不可用的。由于我们利用LLSI来检测高温，我们的方法是非侵入性的，成本更低，并且可扩展到更大的设计。我们报告了恶意RISC-V的实验结果，以证明我们的方法在检测lat方面的有效性。

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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2023 IEEE Computer Society Annual Symposium on VLSI (ISVLSI)

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