Abstract
We present a four-objective optimization method for optimal electroencephalographic (EEG) channel selection to provide access to subjects with permission in a system by detecting intruders and identifying the subject. Each instance was represented by four features computed from two sub-bands, extracted using empirical mode decomposition (EMD) for each channel, and the feature vectors were used as input for one-class/multi-class support vector machines (SVMs). We tested the method on data from the event-related potentials (ERPs) of 26 subjects and 56 channels. The optimization process was performed by the non-dominated sorting genetic algorithm (NSGA), which found a three-channel combination that achieved an accuracy of 0.83, with both a true acceptance rate (TAR) and a true rejection rate (TRR) of 1.00. In the best case, we obtained an accuracy of up to 0.98 for subject identification with a TAR of 0.95 and a TRR 0.93, all using seven EEG channels found by NSGA-III in a subset of subjects manually created. The findings were also validated using 10 different subdivisions of subjects randomly created, obtaining up to 0.97 ± 0.02 of accuracy, a TAR of 0.81 ± 0.12 and TRR of 0.85 ± 0.10 using eight channels found by NSGA-III. These results support further studies on larger datasets for potential applications of EEG in identification and authentication systems.
Highlights
An authentication system includes a stage in which the data is used in a multi-class model with all the subjects in the dataset to identify a specific subject
We evaluated the results using the true acceptance rate (TAR), true rejection rate (TRR), and accuracy of multi-class classification (Table 1)
This study shows the promise of a new biometric system using a novel data source
Summary
An authentication system includes a stage in which the data is used in a multi-class model with all the subjects in the dataset to identify a specific subject. It includes a verification step to compare the data from the claimed subject with that of the true subject alone in the dataset to detect whether the subject is an intruder or not The order of these stages may differ depending on the approach. Four main objectives need to be considered to ensure an optimal global configuration: 1) select the minimum number of relevant EEG channels, 2) reject all intruders, 3) accept all subjects that are already in the system, and 4) identify the subject by multi-class classification. Consideration of these four objectives ensures high-quality results
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