Security Preserving Integration and Resynthesis of Reconfigurable Scan Networks

2020 IEEE International Test Conference (ITC) Pub Date : 2020-11-01 DOI:10.1109/ITC44778.2020.9325227

N. Lylina, A. Atteya, Chih-Hao Wang, H. Wunderlich

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引用次数: 7

Abstract

Reliable operation, test, debug and diagnosis of complex integrated systems are ensured by embedded instruments, such as sensors, aging monitors or Built-In Self-Test (BIST) registers. Reconfigurable Scan Networks (RSNs) offer a flexible and efficient way to access such test instruments throughout the whole life-cycle. However, improper RSN integration might introduce additional connectivity properties to the device under test (DUT), which can be exploited to perform unauthorized access or cause information leakage. The existence of such additional connectivity through the RSN can compromise the security of the DUT and is considered as a security threat.In this paper, a method is presented to resolve all such security compliance violations. The problem is formulated in terms of Integer Linear Programming (ILP) as a minimum cut problem in multicommodity flow. An efficient heuristic is presented, which, to our knowledge, for the first time allows to consider the whole set of violations simultaneously and thereby to find a minimized number of changes to the RSN structure in order to make it compliant with the initial security requirements of the DUT and prevent the information leakage through the scan chain.

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可重构扫描网络的安全保护集成与重构

通过嵌入式仪器，如传感器、老化监视器或内置自检(BIST)寄存器，确保了复杂集成系统的可靠运行、测试、调试和诊断。可重构扫描网络(rsn)为在整个生命周期内访问此类测试仪器提供了一种灵活有效的方法。然而，不适当的RSN集成可能会给被测设备(DUT)引入额外的连接属性，这可能被利用来执行未经授权的访问或导致信息泄漏。通过RSN存在的这种额外连接可能会危及DUT的安全性，并被视为安全威胁。在本文中，提出了一种解决所有此类安全遵从性违规的方法。该问题用整数线性规划(ILP)的形式表述为多商品流中的最小割问题。提出了一种有效的启发式方法，据我们所知，该方法首次允许同时考虑整个违规集，从而找到最小数量的RSN结构更改，以使其符合DUT的初始安全要求，并防止通过扫描链泄露信息。

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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2020 IEEE International Test Conference (ITC)

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