PCB Netlist Obfuscation with Micro Electro Mechanical Systems and Additive Manufacturing Techniques

ISTFA 2021: Conference Proceedings from the 47th International Symposium for Testing and Failure Analysis Pub Date : 2021-10-31 DOI:10.31399/asm.cp.istfa2021p0172

John True, Chengjie Xi, Aslam A. Khan, J. Hihath, N. Asadizanjani

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Abstract

Semiconductor manufacturing has been outsourced to un-trusted regions due to globalization. The complex multistep fabrication of micro-scale integrated circuits (ICs) and the tedious assembly of macro-scale Printed Circuit Boards (PCBs) are vulnerable to malicious attacks from design to final delivery. PCBs provide the functional connections of Integrated Circuits (ICs), sensors, power supplies, etc. of many critical electronic systems for consumers, corporations, and governments. The feature sizes of PCB signal traces in 2D and vias in 3D are an order of magnitude larger than IC devices, and are thereby more vulnerable to non-destructive attacks such as X-ray or probing. Active and passive countermeasures have been successfully developed for IC devices, however PCBs devices are difficult to wholly secure from all attacks. Passive countermeasures for X-ray attacks using high-z materials to block and scatter X-rays are effective, but there is a lack of active and passive countermeasures for PCB. In this paper, a framework for passively obfuscating a PCB's critical connections between components, such as ICs, from non-destructive attacks is demonstrated. This framework can be further extended to incorporate active countermeasures in future work. A proof of concept for a PCB electronic design automation (EDA) tool which combines the small features of micro electro-mechanical systems (MEMS), simulation of X-ray, and 3D PCB Manufacturing to iteratively optimize PCB design to thwart reverse engineering and probing attacks. Index Terms—Additive Manufacturing, MEMS, Hardware Assurance, Physical Inspection, Non-Destructive Technology

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PCB网表混淆与微机电系统和增材制造技术

由于全球化，半导体制造被外包到不受信任的地区。微型集成电路(ic)的复杂多步骤制造和大型印刷电路板(pcb)的繁琐组装从设计到最终交付都容易受到恶意攻击。pcb为消费者、公司和政府提供集成电路(ic)、传感器、电源等许多关键电子系统的功能连接。2D的PCB信号走线和3D的通孔的特征尺寸比IC器件大一个数量级，因此更容易受到x射线或探测等非破坏性攻击。有源和无源对抗措施已经成功地开发用于IC器件，但是pcb器件很难完全免受所有攻击。使用高z材料来阻挡和散射x射线的x射线攻击的被动对策是有效的，但缺乏PCB的主动和被动对策。在本文中，演示了一个框架，用于被动地模糊PCB的组件之间的关键连接，如ic，从非破坏性攻击。这一框架可以进一步扩展，以便在今后的工作中纳入主动对策。PCB电子设计自动化(EDA)工具的概念验证，该工具结合了微机电系统(MEMS)的小功能，x射线模拟和3D PCB制造，以迭代优化PCB设计，以阻止逆向工程和探测攻击。索引术语:增材制造，MEMS，硬件保证，物理检测，无损技术

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ISTFA 2021: Conference Proceedings from the 47th International Symposium for Testing and Failure Analysis

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