PUF-Based Secure Test Wrapper for SoC Testing

2018 IEEE Computer Society Annual Symposium on VLSI (ISVLSI) Pub Date : 2018-07-01 DOI:10.1109/ISVLSI.2018.00127

K. SudeendraKumar, S. Seth, S. Sahoo, Abhishek Mahapatra, Ayass Kant Swain, K. Mahapatra

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引用次数: 1

Abstract

The increased testability and observability due to test structures make chips vulnerable to side channel attacks. The intention of side channel attack are leaking secret keys used in cryptographic cores and getting access to trade related sensitive information stored in chips. Several countermeasures against test based side-channel attacks are available in research literature. One such countermeasure scheme is password based access protection to IEEE 1500 test wrapper, such that only an authentic user with valid password is allowed to access the test structures. IEEE 1500 is a core test standard for enabling the streamlined test integration and test reuse. The trust model of existing schemes assume outsourced assembly and test (OSAT) centre are completely trusted and design house will share secret keys to unlock the IEEE 1500 wrapper during testing. In this paper, we propose a Physical Unclonable Function (PUF) based technique incorporating challenge-response to support comprehensive test security in which there is no need for design house to share secret keys with untrusted OSAT centre to unlock the scan chains. The proposed scheme comes at the cost of reasonable area and performance overhead.

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基于puf的SoC测试安全测试封装器

由于测试结构增加了可测试性和可观察性，使得芯片容易受到侧信道攻击。侧信道攻击的目的是泄露加密核心中使用的密钥，获取存储在芯片中的与交易相关的敏感信息。研究文献中有几种针对基于测试的侧信道攻击的对策。一种这样的对策方案是基于密码的IEEE 1500测试封装器访问保护，这样只有具有有效密码的真实用户才被允许访问测试结构。IEEE 1500是实现流线型测试集成和测试重用的核心测试标准。现有方案的信任模型假设外包组装和测试(OSAT)中心是完全可信的，设计公司将在测试过程中共享密钥以解锁IEEE 1500封装器。在本文中，我们提出了一种基于物理不可克隆功能(PUF)的技术，结合挑战响应来支持全面的测试安全性，在这种技术中，设计公司不需要与不受信任的OSAT中心共享密钥来解锁扫描链。所提出的方案以合理的面积和性能开销为代价。

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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2018 IEEE Computer Society Annual Symposium on VLSI (ISVLSI)

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