Review of Physically Unclonable Functions (PUFs): Structures, Models, and Algorithms

Frontiers in sensors Pub Date : 2022-01-11 DOI:10.3389/fsens.2021.751748

F. Gebali, M. Mamun

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引用次数: 4

Abstract

Physically unclonable functions (PUFs) are now an essential component for strengthening the security of Internet of Things (IoT) edge devices. These devices are an important component in many infrastructure systems such as telehealth, commerce, industry, etc. Traditionally these devices are the weakest link in the security of the system since they have limited storage, processing, and energy resources. Furthermore they are located in unsecured environments and could easily be the target of tampering and various types of attacks. We review in this work the structure of most salient types of PUF systems such as static RAM static random access memory (SRAM), ring oscillator (RO), arbiter PUFs, coating PUFs and dynamic RAM dynamic random access memory (DRAM). We discuss statistical models for the five most common types of PUFs and identify the main parameters defining their performance. We review some of the most recent algorithms that can be used to provide stable authentication and secret key generation without having to use helper data or secure sketch algorithms. Finally we provide results showing the performance of these devices and how they depend on the authentication algorithm used and the main system parameters.

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物理不可控制函数综述：结构、模型和算法

物理上不可克隆的功能（PUF）现在是加强物联网（IoT）边缘设备安全的重要组成部分。这些设备是远程医疗、商业、工业等许多基础设施系统的重要组成部分。传统上，这些设备是系统安全性中最薄弱的环节，因为它们的存储、处理和能源资源有限。此外，它们位于不安全的环境中，很容易成为篡改和各种类型攻击的目标。在这项工作中，我们回顾了最显著类型的PUF系统的结构，如静态RAM静态随机存取存储器（SRAM）、环形振荡器（RO）、仲裁器PUF、涂层PUF和动态RAM动态随机存取存储器。我们讨论了五种最常见类型PUF的统计模型，并确定了定义其性能的主要参数。我们回顾了一些最新的算法，这些算法可以用于提供稳定的身份验证和密钥生成，而不必使用辅助数据或安全草图算法。最后，我们提供的结果显示了这些设备的性能，以及它们如何依赖于所使用的身份验证算法和主要系统参数。

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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Frontiers in sensors

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