Metric Learning in Freewill EEG Pre-Movement and Movement Intention Classification for Brain Machine Interfaces

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Abstract

Decoding movement related intentions is a key step to implement BMIs. Decoding EEG has been challenging due to its low spatial resolution and signal to noise ratio. Metric learning allows finding a representation of data in a way that captures a desired notion of similarity between data points. In this study, we investigate how metric learning can help finding a representation of the data to efficiently classify EEG movement and pre-movement intentions. We evaluate the effectiveness of the obtained representation by comparing classification the performance of a Support Vector Machine (SVM) as a classifier when trained on the original representation, called Euclidean, and representations obtained with three different metric learning algorithms, including Conditional Entropy Metric Learning (CEML), Neighborhood Component Analysis (NCA), and the Entropy Gap Metric Learning (EGML) algorithms. We examine different types of features, such as time and frequency components, which input to the metric learning algorithm, and both linear and non-linear SVM are applied to compare the classification accuracies on a publicly available EEG data set for two subjects (Subject B and C). Although metric learning algorithms do not increase the classification accuracies, their interpretability using an importance measure we define here, helps understanding data organization and how much each EEG channel contributes to the classification. In addition, among the metric learning algorithms we investigated, EGML shows the most robust performance due to its ability to compensate for differences in scale and correlations among variables. Furthermore, from the observed variations of the importance maps on the scalp and the classification accuracy, selecting an appropriate feature such as clipping the frequency range has a significant effect on the outcome of metric learning and subsequent classification. In our case, reducing the range of the frequency components to 0–5 Hz shows the best interpretability in both Subject B and C and classification accuracy for Subject C. Our experiments support potential benefits of using metric learning algorithms by providing visual explanation of the data projections that explain the inter class separations, using importance. This visualizes the contribution of features that can be related to brain function.

Original languageEnglish
Article number902183
JournalFrontiers in Human Neuroscience
Volume16
DOIs
StatePublished - Jul 1 2022

Bibliographical note

Publisher Copyright:
Copyright © 2022 Plucknett, Sanchez Giraldo and Bae.

Funding

This work was partially supported by Electrical and Computer Engineering Undergraduate Research Fellowship and JB and LGSG Start Up Funds. These funds are provided by the Department of Electrical and Computer Engineering at the University of Kentucky. This material is based upon work supported by the Office of the Under Secretary of Defense for Research and Engineering under award number FA9550-21-1-0227.

FundersFunder number
Office of the Under Secretary of Defense for Research and EngineeringFA9550-21-1-0227

    Keywords

    • Electroencephalogram (EEG)
    • brain machine interfaces (BMIs)
    • information theoretic learning (ITL)
    • metric learning (ML)
    • movement intention decoding
    • pre-movement intention decoding
    • readiness potential (RP)
    • support vector machine (SVM)

    ASJC Scopus subject areas

    • Neuropsychology and Physiological Psychology
    • Neurology
    • Psychiatry and Mental health
    • Biological Psychiatry
    • Behavioral Neuroscience

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