Abstract
The study of brain electrical activity (BEA) from different cognitive conditions has attracted a lot of interest in the last decade due to the high number of possible applications that could be generated from it. In this work, a discriminative framework for BEA via electroencephalography (EEG) is proposed based on multi-output Gaussian Processes (MOGPs) with a specialized spectral kernel. First, a signal segmentation stage is executed, and the channels from the EEG are used as the model outputs. Then, a novel covariance function within the MOGP known as the multispectral mixture kernel (MOSM) allows us to find and quantify the relationships between different channels. Several MOGPs are trained from different conditions grouped in bi-class problems, and the discrimination is performed based on the likelihood score of the test signals against all the models. Finally, the mean likelihood is computed to predict the correspondence of new inputs with each class’s existing models. Results show that this framework allows us to model the EEG signals adequately using generative models and allows analyzing the relationships between channels of the EEG for a particular condition. At the same time, the set of trained MOGPs is well suited to discriminate new input data.
Highlights
IntroductionEach physiological or cognitive process will produce a particular pattern of electrical interactions linking neurons from different brain regions
From the neuroscience perspective, each physiological or cognitive process will produce a particular pattern of electrical interactions linking neurons from different brain regions
We propose the extension of multi-output Gaussian Processes (MOGPs) with an multi-output spectral mixture (MOSM) kernel for brain electrical activity (BEA) discrimination, termed MOSM-Gaussian Processes (GPs)
Summary
Each physiological or cognitive process will produce a particular pattern of electrical interactions linking neurons from different brain regions. Capturing BEA by placing a set of electrodes over the scalp, known as electroencephalography (EEG), gathers and amplifies currents reflected in the brain cortex from all the possible brain sources, yielding a mixture of latent activity sources at each channel. For discovering such a latent activity, the literature considers different types of EEG analyses ranging from time and spectral domain processing [3,4], through connectivity measures between channels [5], to the complex network analysis [6]
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