Abstract
The risk of personal data exposure through unauthorized access has never been as imminent as today. To counter this, biometric authentication has been proposed: the use of distinctive physiological and behavioral characteristics as a form of identification and access control. One of the recent developments is electroencephalography (EEG)-based authentication. It builds on the subject-specific nature of brain responses which are difficult to recreate artificially. We propose an authentication system based on EEG signals recorded in response to a simple motor paradigm. Authentication is achieved with a novel two-stage decoder. In the first stage, EEG signal features are extracted using an inception- and a VGG-like deep learning neural network (NN) both of which we compare with principal component analysis (PCA). In the second stage, a support vector machine (SVM) is used for binary classification to authenticate the subject based on the extracted features. All decoders are trained on EEG motor-movement data recorded from 105 subjects. We achieved with the VGG-like NN-SVM decoder a false-acceptance rate (FAR) of 2.55% with an overall accuracy of 88.29%, a FAR of 3.33% with an accuracy of 87.47%, and a FAR of 2.89% with an accuracy of 90.68% for 8, 16, and 64 channels, respectively. With the Inception-like NN-SVM decoder we achieved a false-acceptance rate (FAR) of 4.08% with an overall accuracy of 87.29%, a FAR of 3.53% with an accuracy of 85.31%, and a FAR of 1.27% with an accuracy of 93.40% for 8, 16, and 64 channels, respectively. The PCA-SVM decoder achieved accuracies of 92.09%, 92.36%, and 95.64% with FARs of 2.19%, 2.17%, and 1.26% for 8, 16, and 64 channels, respectively.
Highlights
Along with the evolution in digital information acquisition and storage is the need for increasingly more advanced authorization systems
We achieved with the VGG-like neural network (NN)-support vector machine (SVM) decoder a false-acceptance rate (FAR) of 2.55% with an overall accuracy of 88.29%, a FAR of 3.33% with an accuracy of 87.47%, and a FAR of 2.89% with an accuracy of
Accuracies are higher than 85%, the highest one is for the principal component analysis (PCA)-SVM system for 64 channels (95.64%), with a concurrent maximum value for the FAR
Summary
Along with the evolution in digital information acquisition and storage is the need for increasingly more advanced authorization systems. Such systems require individuals to produce a highly specific phrase, word, or feature to obtain access. Other bodily parameters and signals have successfully been used for authentication for example fingerprints, iris scans, and writing patterns. This branch of security systems is called biometric authorization [1]. A secure authorization system requires features to be user-related and difficult to simulate [1,2]. Electroencephalography (EEG) has been suggested as a biometric credential [3,4] due to its subject-specific and unbidden nature
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