Riemannian Geometry-Preserving Variational Autoencoder for MI-BCI Data Augmentation
Abstract
This paper addresses the challenge of generating synthetic electroencephalogram (EEG) covariance matrices for motor imagery brain-computer interface (MI-BCI) applications. Objective: We aim to develop a generative model capable of producing high-fidelity synthetic covariance matrices while preserving their symmetric positive-definite nature. Approach: We propose a Riemannian geometry-preserving variational autoencoder (RGP-VAE) integrating geometric mappings with a composite loss function combining Riemannian distance, tangent space reconstruction accuracy and generative diversity. Results: The model generates valid, representative EEG covariance matrices, while learning a subject-invariant latent space. Synthetic data proves practically useful for MI-BCI, with its impact depending on the paired classifier. Contribution: This work introduces and validates the RGP-VAE as a geometry-preserving generative model for EEG covariance matrices, highlighting its potential for signal privacy, scalability and data augmentation.
Keywords
Cite
@article{arxiv.2603.10563,
title = {Riemannian Geometry-Preserving Variational Autoencoder for MI-BCI Data Augmentation},
author = {Viktorija Poļaka and Ivo Pascal de Jong and Andreea Ioana Sburlea},
journal= {arXiv preprint arXiv:2603.10563},
year = {2026}
}
Comments
6 pages, 4 figures, 2 tables