利用带有胶囊自动编码器网络的深度学习模型进行侧信道攻击检测

IF 2.5 4区 计算机科学 Q3 TELECOMMUNICATIONS
Raja Maheswari, Marudhamuthu Krishnamurthy
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引用次数: 0

摘要

侧信道分析(SCA)是一种密码分析攻击,它通过在现实世界中执行密码算法,利用意外的 "侧信道 "泄漏来破解嵌入式系统的密钥。这些侧信道错误可以通过跟踪执行该技术的设备的能耗、加密过程中的电磁辐射、执行时间、缓存命中/遗漏等情况来发现。如今,基于深度学习的检测技术被认为是新兴的攻击检测技术。与机器学习模型相比,深度学习架构具有自主学习和专注于困难特征的能力。鉴于这些因素,这项工作的动机被认为是提出一种基于深度学习的攻击检测方法。目前有许多方法可用于减少这些攻击,但大多数方法效率低下且耗时较长。为了应对这些挑战,本研究采用了一种新颖的基于深度学习的方法。预处理、特征提取和 SCA 分类是本研究提出的方法的三个阶段。首先,预处理用于去除不必要的信息,并通过数据清理和最小-最大归一化来提高输入的质量。然后,将先前处理过的数据作为输入输入到所提出的混合深度学习架构中。研究中引入了深度残差胶囊自动编码器(DR_CAE)模型。在这种情况下,利用深度残差神经网络-50(DRNN-50)来提取相关特征,而侧信道分析则通过胶囊自动编码器(CAE)来完成。为了提高模型的性能,使用了改良白鲨优化(MWSO)技术来调整模型的参数。在结果部分,从准确度、精确度、召回率、F-度量、时间等方面对所提出的模型与现有的各种模型进行了比较。提出的框架准确率为 98.802%,F-measures 为 98.801%,kappa 系数为 97.6%,精确率为 98.81%,召回率为 98.80%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A profiled side-channel attack detection using deep learning model with capsule auto-encoder network

A profiled side-channel attack detection using deep learning model with capsule auto-encoder network

Side-channel analysis (SCA) is a type of cryptanalytic attack that uses unintended ‘side-channel’ leakage through the real-world execution of the cryptographic algorithm to crack a secret key of an embedded system. These side-channel errors can be discovered through tracking the energy usage of the device performing the technique, electromagnetic radiations while the encryption process, execution time, cache hits/misses, and others. Nowadays, deep learning-based detection techniques are considered as emerging techniques that have been proposed for attack detection. Deep learning architectures have the ability to learn autonomously and concentrate on difficult features, in contrast to machine learning models. In light of these factors, the work's motive is thought to be the proposal of a deep learning-based attack detection method. Many methods are used to decrease these assaults, however, the majority of them are inefficient and time-demanding. In order to address these challenges, this study employs a novel deep learning-based methodology. Pre-processing, feature extraction, and SCA classification are the three stages of the approach proposed in this work. First, pre-processing is used to remove unnecessary information and improve the quality of the input using data cleaning and min-max normalization. The previously processed data are then fed as input into the proposed hybrid deep learning architecture. A Deep Residual Capsule Auto-Encoder (DR_CAE) model is introduced in the proposed study. The deep residual neural network-50 (DRNN-50) is utilized to extract relevant features in this case, while the side channel analysis is done by using capsule auto-encoder (CAE). The parameters of the proposed model are adjusted using the modified white shark optimization (MWSO) technique to improve its performance. In the results section, the proposed model is compared to various existing models in terms of accuracy, precision, recall, F-measures, time, and so on. The proposed framework has an accuracy of 98.802%, F-measures of 98.801%, kappa coefficient of 97.6%, the precision value of 98.81%, and recall value of 98.80%.

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来源期刊
CiteScore
8.90
自引率
13.90%
发文量
249
期刊介绍: ransactions on Emerging Telecommunications Technologies (ETT), formerly known as European Transactions on Telecommunications (ETT), has the following aims: - to attract cutting-edge publications from leading researchers and research groups around the world - to become a highly cited source of timely research findings in emerging fields of telecommunications - to limit revision and publication cycles to a few months and thus significantly increase attractiveness to publish - to become the leading journal for publishing the latest developments in telecommunications
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