A Bayesian Tri-Level Optimization Framework for Optimal EEG Channel Selection in Seizure Prediction

Authors
Abstract
In this study, a tri-level optimization framework is proposed for optimal EEG channel selection with the aim of improving seizure prediction accuracy. This approach is grounded in Bayesian theory and developed based on principles of tri-level optimization methods. In the first level, the conditional probability derived from the correlation between temporal segments of preictal and ictal EEG signals is calculated. By incorporating the prior probability, the posterior probability is modeled and optimized as the objective function of the first level, which is applied, at the second level, to determine the optimal seizure prediction time for each channel, representing the earliest moment when seizure-related information becomes evident in that channel. The third-level optimization problem seeks to identify the optimal EEG channel using the optimal timing of each channel. This tri-level process ensures the selection of a channel that not only minimizes prediction delay but also provides the most informative signal for the system. The implementation of this method on real data from 14 patients with epilepsy demonstrates that the proposed approach can achieve an efficient trade-off between prediction accuracy and model complexity.
Keywords

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