通过非破坏性红外(IR)光谱材料表征,机器学习辅助伪造IC检测

Chengjie Xi, Nathan Jessurun, John True, Aslam A. Khan, M. Tehranipoor, N. Asadizanjani
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引用次数: 1

摘要

如今,由于供应链全球化的不断发展,假冒集成电路(IC)越来越普遍。这种供应链漏洞导致不可靠和不安全的假冒ic集成到许多应用程序的最终用户设备中,包括消费者,企业和军事领域。各种方法,如老化检测传感器、物理不可克隆功能(puf)和硬件计量已经开发出来,以便在这些假冒产品集成到关键系统之前检测到它们。然而,检测和预防的几个复杂方面限制了它们作为假冒问题的权宜之计的使用。因此,迫切需要新的检查和保证技术,这些技术需要对设备电路或材料进行最小或不需要额外的更改/修改,同时保持每个样品的低成本。本文通过对仿冒和正品IC之间的初步材料调查,证明了利用IC封装材料特性进行防伪检测的可能性。本研究使用漫反射红外傅里叶变换光谱(DRIFT)作为材料表征,材料光谱将用于训练机器学习分类模型。将测试几种机器学习分类方法,如线性判别分析(LDA),支持向量机(SVM),随机森林(RF)和多层感知器(MLP)。在标准正态变量(SNV)数据预处理和MPL模型的帮助下,假品与正品样本鉴别的准确率达到92%以上。这证明了假冒和正品IC样品之间存在包装材料差异。
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Machine Learning Assisted Counterfeit IC Detection through Non-destructive Infrared (IR) Spectroscopy Material Characterization
Nowadays, counterfeit integrated circuits (IC) are increasingly common due to the continuous growth of supply chain globalization. This supply chain vulnerability results in unreliable and insecure counterfeit ICs integrated into the end-user devices in many applications, including consumer, corporate, and military domains. Various methods such as aging detection sensors, Physical Unclonable Functions (PUFs), and hardware metering have been developed to detect such counterfeits before they become integrated into critical systems. However, several complicated aspects of detection and prevention limit their use as a stopgap to the counterfeit problem. Hence, there is a critical need for novel inspection and assurance techniques that require minimal or no additional changes/modifications to the device circuit or material while remaining low-cost per sample. In this paper, the possibility of using IC packaging material characterization for counterfeit detection is proved by a preliminary material survey between the counterfeit and authentic ICs. Diffuse Reflectance Infrared Fourier Transform Spectroscopy (DRIFT) is used as the material characterization in this research, and the material spectrums will be utilized for training machine learning classification models. Several machine learning classification methods will be tested, such as Linear discriminant analysis (LDA), Support Vector Machine (SVM), random forest(RF), and multi-layer perceptron (MLP). With the help of the Standard Normal Variate (SNV) data preprocessing and MPL model, over 92 percent accuracy of counterfeit versus genuine sample discrimination has been achieved. This proves the existence of packaging material differences between counterfeit and authentic IC samples.
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