Related papers: TypeNet: Deep Learning Keystroke Biometrics

TypeNet: Deep Learning Keystroke Biometrics

URL: http://arxiv.org/abs/2101.05570v2
Date: Thu, 18 Feb 2021 17:40:57 GMT
Title: TypeNet: Deep Learning Keystroke Biometrics
Authors: Alejandro Acien and Aythami Morales and John V. Monaco and Ruben Vera-Rodriguez and Julian Fierrez
Abstract summary: We introduce TypeNet, a Recurrent Neural Network trained with a moderate number of keystrokes per identity. With 5 gallery sequences and test sequences of length 50, TypeNet achieves state-of-the-art keystroke biometric authentication performance. Our experiments demonstrate a moderate increase in error with up to 100,000 subjects, demonstrating the potential of TypeNet to operate at an Internet scale.
Score: 77.80092630558305
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: We study the performance of Long Short-Term Memory networks for keystroke biometric authentication at large scale in free-text scenarios. For this we introduce TypeNet, a Recurrent Neural Network (RNN) trained with a moderate number of keystrokes per identity. We evaluate different learning approaches depending on the loss function (softmax, contrastive, and triplet loss), number of gallery samples, length of the keystroke sequences, and device type (physical vs touchscreen keyboard). With 5 gallery sequences and test sequences of length 50, TypeNet achieves state-of-the-art keystroke biometric authentication performance with an Equal Error Rate of 2.2% and 9.2% for physical and touchscreen keyboards, respectively, significantly outperforming previous approaches. Our experiments demonstrate a moderate increase in error with up to 100,000 subjects, demonstrating the potential of TypeNet to operate at an Internet scale. We utilize two Aalto University keystroke databases, one captured on physical keyboards and the second on mobile devices (touchscreen keyboards). To the best of our knowledge, both databases are the largest existing free-text keystroke databases available for research with more than 136 million keystrokes from 168,000 subjects in physical keyboards, and 60,000 subjects with more than 63 million keystrokes acquired on mobile touchscreens.

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