Acoustic integrity codes: secure device pairing using short-range acoustic communication

Proceedings of the 13th ACM Conference on Security and Privacy in Wireless and Mobile Networks Pub Date : 2020-05-18 DOI:10.1145/3395351.3399420

Florentin Putz, Flor Álvarez, J. Classen

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引用次数: 7

Abstract

Secure Device Pairing (SDP) relies on an out-of-band channel to authenticate devices. This requires a common hardware interface, which limits the use of existing SDP systems. We propose to use short-range acoustic communication for the initial pairing. Audio hardware is commonly available on existing off-the-shelf devices and can be accessed from user space without requiring firmware or hardware modifications. We improve upon previous approaches by designing Acoustic Integrity Codes (AICs): a modulation scheme that provides message authentication on the acoustic physical layer. We analyze their security and demonstrate that we can defend against signal cancellation attacks by designing signals with low autocorrelation. Our system can detect overshadowing attacks using a ternary decision function with a threshold. In our evaluation of this SDP scheme's security and robustness, we achieve a bit error ratio below 0.1% for a net bit rate of 100 bps with a signal-to-noise ratio (SNR) of 14 dB. Using our open-source proof-of-concept implementation on Android smartphones, we demonstrate pairing between different smartphone models.

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声学完整性代码:使用短距离声学通信的安全设备配对

SDP (Secure Device Pairing)是指通过带外通道对设备进行认证。这需要一个通用的硬件接口，这限制了现有SDP系统的使用。我们建议使用短距离声学通信进行初始配对。音频硬件通常可以在现有的现成设备上使用，并且可以从用户空间访问，而无需修改固件或硬件。我们通过设计声学完整性码(aic)改进了以前的方法:一种在声学物理层上提供消息认证的调制方案。我们分析了它们的安全性，并证明我们可以通过设计低自相关的信号来防御信号抵消攻击。我们的系统可以使用带有阈值的三元决策函数来检测阴影攻击。在我们对该SDP方案的安全性和鲁棒性的评估中，我们实现了误码率低于0.1%，净比特率为100 bps，信噪比(SNR)为14 dB。使用我们在Android智能手机上的开源概念验证实现，我们演示了不同智能手机型号之间的配对。

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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Proceedings of the 13th ACM Conference on Security and Privacy in Wireless and Mobile Networks

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