SafeGait: Safeguarding Gait-based Key Generation against Vision-based Side Channel Attack Using Generative Adversarial Network

Yuezhong Wu, Mahbub Hassan, Wen Hu
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引用次数: 2

Abstract

Recent works have shown that wearable or implanted devices attached at different locations of the body can generate an identical security key from their independent measurements of the same gait. This has created an opportunity to realize highly secured data exchange to and from critical implanted devices. In this paper, we first demonstrate that vision can be used to easily attack such gait-based key generations; an attacker with a commodity camera can measure the gait from a distance and generate a security key with any target wearable or implanted device faster than other legitimate devices worn at different locations of the subject’s body. To counter the attack, we propose a firewall to stop video-based gait measurements to proceed with key generation, but letting measurements from inertial measurement units (IMUs) that are widely used in wearable devices to measure the gait accelerations from the body to proceed. We implement the firewall concept with an IMU-vs-Video binary classifier that combines InceptionTime, an ensemble of deep Convolutional Neural Network (CNN) models for effective feature extraction from gait measurements, to a Generative Adversarial Network (GAN) that can generalize the classifier across subjects. Comprehensive evaluation with a real-world dataset shows that our proposed classifier can perform with an accuracy of 97.82%. Given that an attacker has to fool the classifier for multiple consecutive gait cycles to generate the complete key, the high single-cycle classification accuracy results in an extremely low probability for a video attacker to successfully pair with a target wearable device. More precisely, a video attacker would have one in a billion chance to successfully generate a 128-bit key, which would require the attacker to observe the subject for thousands of years.
安全防护:利用生成对抗网络保护基于步态的密钥生成免受基于视觉的侧信道攻击
最近的研究表明,安装在身体不同位置的可穿戴或植入设备可以通过对相同步态的独立测量产生相同的安全密钥。这为实现关键植入设备之间的高度安全数据交换创造了机会。在本文中,我们首先证明了视觉可以很容易地攻击这种基于步态的密钥代;使用普通摄像机的攻击者可以从远处测量步态,并与任何目标可穿戴或植入设备生成安全密钥,比在受试者身体不同位置佩戴的其他合法设备更快。为了对抗攻击,我们提出了一个防火墙来阻止基于视频的步态测量继续进行密钥生成,但让惯性测量单元(imu)的测量继续进行,惯性测量单元(imu)在可穿戴设备中广泛用于测量来自身体的步态加速度。我们使用IMU-vs-Video二元分类器实现防火墙概念,该分类器将InceptionTime(用于从步态测量中有效提取特征的深度卷积神经网络(CNN)模型的集合)与生成对抗网络(GAN)相结合,可以跨主题推广分类器。对真实数据集的综合评估表明,我们提出的分类器可以达到97.82%的准确率。考虑到攻击者必须欺骗分类器连续多个步态周期才能生成完整的密钥,高单周期分类精度导致视频攻击者成功配对目标可穿戴设备的概率极低。更准确地说,视频攻击者只有十亿分之一的机会成功生成128位密钥,这需要攻击者观察目标数千年。
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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