A Small Tamper-Resistant Anti-Recycling IC Sensor With a Reused I/O Interface and DC Signalling

IF 2.4 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE open journal of circuits and systems Pub Date : 2024-10-28 DOI:10.1109/OJCAS.2024.3487072
Alexandros Dimopoulos;Mihai Sima;Stephen W. Neville
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Abstract

Counterfeit electronic components are known to enter supply chains through recycling, with these already-aged components creating serious reliability risks, particularly for critical infrastructure systems. A number of recycled integrated circuit (IC) risk mitigation approaches have been proposed, but these generally lack pragmatic feasibility. This work proposes a novel real-world deployable on-chip sensor that: 1) is tamper-resistant by exploiting persistent changes caused by hot carrier injection (HCI); 2) generates a DC signal measurable by common low-cost test equipment; and 3) reuses an existing I/O interface, including existing pins; while 4) requiring a very small footprint. Combining this sensor with a random sample-based testing strategy allows for low-cost and time efficient detection of fraudulently recycled batches of ICs. Through simulation-based validation using process-accurate models of a 65 nm technology we show that employing a random sample size as small as 130 is sufficient for identifying such batches with a statistical significance level of 0.01.
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带有重复使用的输入/输出接口和直流信号的小型防篡改、防回收集成电路传感器
众所周知,假冒电子元件会通过回收进入供应链,这些已经老化的元件会带来严重的可靠性风险,尤其是对关键基础设施系统而言。目前已经提出了许多降低回收集成电路(IC)风险的方法,但这些方法普遍缺乏实际可行性。这项工作提出了一种新颖的、可在现实世界部署的片上传感器,它具有以下特点1)利用热载流子注入(HCI)引起的持续变化,具有防篡改能力;2)产生的直流信号可由普通低成本测试设备测量;3)重复使用现有的 I/O 接口,包括现有的引脚;4)只需很小的占地面积。将该传感器与随机抽样测试策略相结合,可以低成本、高效率地检测出欺诈性回收的集成电路批次。通过使用 65 纳米技术的工艺精确模型进行基于模拟的验证,我们发现采用小至 130 个随机样本就足以识别此类批次,统计显著性水平为 0.01。
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