A Practical Deep Learning-Based Acoustic Side Channel Attack on Keyboards
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With recent developments in deep learning, the ubiquity of micro-phones and the rise in online services via personal devices, acoustic side channel attacks present a greater threat to keyboards than ever. This paper presents a practical implementation of a state-of-the-art deep learning model in order to classify laptop keystrokes, using a smartphone integrated microphone. When trained on keystrokes recorded by a nearby phone, the classifier achieved an accuracy of 95%, the highest accuracy seen without the use of a language model. When trained on keystrokes recorded using the video-conferencing software Zoom, an accuracy of 93% was achieved, a new best for the medium. Our results prove the practicality of these side channel attacks via off-the-shelf equipment and algorithms. We discuss a series of mitigation methods to protect users against these series of attacks.
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Forward citations
Cited by 2 Pith papers
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Impact Analysis of Speech Representation Learning Models for Acoustic Side-Channel Attack
KEYAC dataset created; KAN fine-tuning achieves SOTA on acoustic side-channel keystroke recognition from speech representations under zero-shot and partial fine-tuning.
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Impact Analysis of Speech Representation Learning Models for Acoustic Side-Channel Attack
KEYAC dataset benchmarks speech models for keyboard acoustic side-channel attacks, with KAN fine-tuning setting new SOTA by addressing nonlinear feature interactions.
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