A Highly Stable XOR APUF Based on Deviation Signal Screening Mechanism

IF 0.8 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Ieice Electronics Express Pub Date : 2023-11-10 DOI:10.1587/elex.20.20230377

Guanbao Zhai, Pengjun Wang, Gang Li, Youyi Zhuang

引用次数: 0

Abstract

By using the XOR method to obfuscate response of Arbiter PUFs (APUFs), the ability to resist machine learning (ML) modeling attacks can be improved, but this method will reduce the stable of PUF to a certain extent, making PUF lose usability. In view of this, a highly stable XOR APUF (HS-XOR APUF) circuit is proposed by studying the generation mechanism of unstable response bits and the screening characteristics of the logic gates delay signals. First, the maximum and minimum delay signals are screened with AND/OR gate to generate highly stable response bits; Then, by inserting a inverter in the APUF switch unit, the delay time of the signal is increased, and the influence of environmental factors on the comparison signal with small delay deviation is weakened; Finally, the FPGA experimental results show that the response stability of HS-XOR APUF is rarely affected by the count of XOR units, and the AND/OR gate delay signal screening structure is simple and consumes a small amount of hardware resources, which can be widely used in the fields of information security.

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基于偏差信号筛选机制的高稳定XOR APUF

通过XOR方法对Arbiter PUF (apuf)的响应进行模糊处理，可以提高其抵抗机器学习(ML)建模攻击的能力，但这种方法会在一定程度上降低PUF的稳定性，使PUF失去可用性。鉴于此，通过研究不稳定响应位的产生机理和逻辑门延迟信号的筛选特性，提出了一种高稳定的XOR APUF (HS-XOR APUF)电路。首先，用and /OR门对最大和最小延迟信号进行筛选，产生高度稳定的响应位;然后，通过在APUF开关单元中插入逆变器，增加信号的延时时间，减弱环境因素对延时偏差较小的比较信号的影响;最后，FPGA实验结果表明，HS-XOR APUF的响应稳定性很少受到XOR单元数量的影响，且与/或门延迟信号筛选结构简单，消耗硬件资源少，可广泛应用于信息安全领域。

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

Ieice Electronics Express 工程技术-工程：电子与电气

CiteScore

1.50

自引率

37.50%

发文量

119

审稿时长

1.1 months

期刊介绍： An aim of ELEX is rapid publication of original, peer-reviewed short papers that treat the field of modern electronics and electrical engineering. The boundaries of acceptable fields are not strictly delimited and they are flexibly varied to reflect trends of the fields. The scope of ELEX has mainly been focused on device and circuit technologies. Current appropriate topics include: - Integrated optoelectronics (lasers and optoelectronic devices, silicon photonics, planar lightwave circuits, polymer optical circuits, etc.) - Optical hardware (fiber optics, microwave photonics, optical interconnects, photonic signal processing, photonic integration and modules, optical sensing, etc.) - Electromagnetic theory - Microwave and millimeter-wave devices, circuits, and modules - THz devices, circuits and modules - Electron devices, circuits and modules (silicon, compound semiconductor, organic and novel materials) - Integrated circuits (memory, logic, analog, RF, sensor) - Power devices and circuits - Micro- or nano-electromechanical systems - Circuits and modules for storage - Superconducting electronics - Energy harvesting devices, circuits and modules - Circuits and modules for electronic displays - Circuits and modules for electronic instrumentation - Devices, circuits and modules for IoT and biomedical applications