Riemannian geometry has been applied to Brain Computer Interface (BCI) for brain signals classification yielding promising results. Studying electroencephalographic (EEG) signals from their associated covariance matrices allows a mitigation of common sources of variability (electronic, electrical, biological) by constructing a representation which is invariant to these perturbations. While working in Euclidean space with covariance matrices is known to be error-prone, one might take advantage of algorithmic advances in information geometry and matrix manifold to implement methods for Symmetric Positive-Definite (SPD) matrices. This paper proposes a comprehensive review of the actual tools of information geometry and how they could be applied on covariance matrices of EEG. In practice, covariance matrices should be estimated, thus a thorough study of all estimators is conducted on real EEG dataset. As a main contribution, this paper proposes an online implementation of a classifier in the Riemannian space and its subsequent assessment in Steady-State Visually Evoked Potential (SSVEP) experimentations.
@article{arxiv.1501.03227,
title = {Using Riemannian geometry for SSVEP-based Brain Computer Interface},
author = {Emmanuel K. Kalunga and Sylvain Chevallier and Quentin Barthelemy},
journal= {arXiv preprint arXiv:1501.03227},
year = {2021}
}
Comments
29 pages, 6 figures, 1 table, research report. Update on the overall text, most of the figure are modified, the algorithm is explained more clearly, updated comparisons with state of the art methods