B-TREPID: Batteryless tamper-resistant envelope with a PUF and integrity detection

2018 IEEE International Symposium on Hardware Oriented Security and Trust (HOST) Pub Date : 2018-04-01 DOI:10.1109/HST.2018.8383890

Vincent Immler, J. Obermaier, Martin König, Matthias Hiller, G. Sigl

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引用次数: 26

Abstract

Protecting embedded devices against physical attacks is a challenging task since the attacker has control of the device in a hostile environment. To address this issue, current countermeasures typically use a battery-backed tamper-respondent envelope that encloses the entire device to create a trusted compartment. However, the battery affects the system's robustness and weight, and also leads to difficulties with the security mechanism while shipping the device. In contrast, we present a batteryless tamper-resistant envelope, which contains a fine mesh of electrodes, and its complementary security concept. An evaluation unit checks the integrity of the sensor mesh by detecting short and open circuits. Additionally, it measures the capacitances of the mesh. Once its preliminary integrity is confirmed, a cryptographic key is derived from the capacitive measurements that represent a PUF, to decrypt and authenticate the firmware of the enclosed host system. We demonstrate the feasibility of our concept, provide details on the layout and electrical properties of the batteryless envelope, and explain the underlying security architecture. Practical results from a set of manufactured envelopes facilitate future research.

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B-TREPID:带PUF和完整性检测的无电池防篡改信封

保护嵌入式设备免受物理攻击是一项具有挑战性的任务，因为攻击者可以在敌对环境中控制设备。为了解决这个问题，目前的对策通常使用电池支持的篡改应答信封，该信封将整个设备封闭起来，以创建一个可信的隔间。然而，电池会影响系统的坚固性和重量，并且在运输设备时也会导致安全机制的困难。相比之下，我们提出了一种无电池防篡改信封，它包含一个精细的电极网，以及它的补充安全概念。评估单元通过检测短路和开路来检查传感器网格的完整性。此外，它还测量网格的电容。一旦其初步完整性得到确认，就会从表示PUF的电容性测量中获得加密密钥，以解密和验证封闭主机系统的固件。我们展示了我们的概念的可行性，提供了关于无电池外壳的布局和电气特性的详细信息，并解释了底层的安全架构。从一套制造信封的实际结果有助于未来的研究。

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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来源期刊

2018 IEEE International Symposium on Hardware Oriented Security and Trust (HOST)

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