A Conditionally Chaotic Physically Unclonable Function Design Framework with High Reliability

Saranyu Chattopadhyay, Pranesh Santikellur, R. Chakraborty, J. Mathew, M. Ottavi
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引用次数: 2

Abstract

Physically Unclonable Function (PUF) circuits are promising low-overhead hardware security primitives, but are often gravely susceptible to machine learning–based modeling attacks. Recently, chaotic PUF circuits have been proposed that show greater robustness to modeling attacks. However, they often suffer from unacceptable overhead, and their analog components are susceptible to low reliability. In this article, we propose the concept of a conditionally chaotic PUF that enhances the reliability of the analog components of a chaotic PUF circuit to a level at par with their digital counterparts. A conditionally chaotic PUF has two modes of operation: bistable and chaotic , and switching between these two modes is conveniently achieved by setting a mode-control bit (at a secret position) in an applied input challenge. We exemplify our PUF design framework for two different PUF variants—the CMOS Arbiter PUF and a previously proposed hybrid CMOS-memristor PUF, combined with a hardware realization of the Lorenz system as the chaotic component. Through detailed circuit simulation and modeling attack experiments, we demonstrate that the proposed PUF circuits are highly robust to modeling and cryptanalytic attacks, without degrading the reliability of the original PUF that was combined with the chaotic circuit, and incurs acceptable hardware footprint.
一种高可靠性条件混沌物理不可克隆功能设计框架
物理不可克隆功能(PUF)电路是一种很有前途的低开销硬件安全原语,但通常很容易受到基于机器学习的建模攻击。最近,混沌PUF电路被提出,对建模攻击表现出更强的鲁棒性。然而,它们经常承受不可接受的开销,并且它们的模拟组件容易受到低可靠性的影响。在本文中,我们提出了条件混沌PUF的概念,该概念将混沌PUF电路的模拟组件的可靠性提高到与数字组件相当的水平。条件混沌PUF有两种工作模式:双稳态和混沌,通过在应用的输入挑战中设置模式控制位(在秘密位置),可以方便地在这两种模式之间切换。我们举例说明了两种不同PUF变体的PUF设计框架——CMOS Arbiter PUF和先前提出的CMOS-忆阻器混合PUF,并结合了洛伦兹系统作为混沌组件的硬件实现。通过详细的电路仿真和建模攻击实验,我们证明了所提出的PUF电路对建模和密码分析攻击具有很高的鲁棒性,不会降低与混沌电路结合的原始PUF的可靠性,并且会产生可接受的硬件占用。
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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