EarSlide: a Secure Ear Wearables Biometric Authentication Based on Acoustic Fingerprint

Zi Wang, Yilin Wang, Jie Yang
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Abstract

Ear wearables (earables) are emerging platforms that are broadly adopted in various applications. There is an increasing demand for robust earables authentication because of the growing amount of sensitive information and the IoT devices that the earable could access. Traditional authentication methods become less feasible due to the limited input interface of earables. Nevertheless, the rich head-related sensing capabilities of earables can be exploited to capture human biometrics. In this paper, we propose EarSlide, an earable biometric authentication system utilizing the advanced sensing capacities of earables and the distinctive features of acoustic fingerprints when users slide their fingers on the face. It utilizes the inward-facing microphone of the earables and the face-ear channel of the ear canal to reliably capture the acoustic fingerprint. In particular, we study the theory of friction sound and categorize the characteristics of the acoustic fingerprints into three representative classes, pattern-class, ridge-groove-class, and coupling-class. Different from traditional fingerprint authentication only utilizes 2D patterns, we incorporate the 3D information in acoustic fingerprint and indirectly sense the fingerprint for authentication. We then design representative sliding gestures that carry rich information about the acoustic fingerprint while being easy to perform. It then extracts multi-class acoustic fingerprint features to reflect the inherent acoustic fingerprint characteristic for authentication. We also adopt an adaptable authentication model and a user behavior mitigation strategy to effectively authenticate legit users from adversaries. The key advantages of EarSlide are that it is resistant to spoofing attacks and its wide acceptability. Our evaluation of EarSlide in diverse real-world environments with intervals over one year shows that EarSlide achieves an average balanced accuracy rate of 98.37% with only one sliding gesture.
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EarSlide:基于声学指纹的安全耳戴式生物识别认证技术
耳戴式设备(耳可穿戴设备)是一种新兴平台,在各种应用中被广泛采用。由于耳戴式设备可以访问越来越多的敏感信息和物联网设备,因此对强大的耳戴式设备身份验证的需求日益增长。由于耳机的输入接口有限,传统的身份验证方法变得不那么可行。然而,我们可以利用耳机丰富的头部相关传感能力来捕捉人体生物特征。在本文中,我们提出了耳滑式生物识别身份验证系统(EarSlide),它利用了耳机先进的传感能力和用户手指在面部滑动时声学指纹的独特特征。它利用耳机朝内的麦克风和耳道的面耳通道来可靠地捕捉声学指纹。我们特别研究了摩擦音理论,并将声学指纹的特征分为三个具有代表性的类别:花纹类、脊沟类和耦合类。与传统的指纹认证仅利用二维图案不同,我们在声学指纹中加入了三维信息,间接感知指纹进行认证。然后,我们设计了具有代表性的滑动手势,这些手势既包含丰富的声学指纹信息,又易于操作。然后提取多类声学指纹特征,以反映声学指纹的固有特性,用于身份验证。我们还采用了一种适应性强的认证模型和一种用户行为缓解策略,以有效地认证合法用户,防止被对手利用。EarSlide 的主要优势在于它能抵御欺骗攻击,并具有广泛的可接受性。我们在不同的真实环境中对 EarSlide 进行了为期一年的评估,结果表明,EarSlide 只需一个滑动手势即可达到 98.37% 的平均平衡准确率。
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