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EEG2Vec: Learning Affective EEG Representations via Variational Autoencoders

Machine Learning 2022-08-08 v2 Artificial Intelligence Signal Processing

Abstract

There is a growing need for sparse representational formats of human affective states that can be utilized in scenarios with limited computational memory resources. We explore whether representing neural data, in response to emotional stimuli, in a latent vector space can serve to both predict emotional states as well as generate synthetic EEG data that are participant- and/or emotion-specific. We propose a conditional variational autoencoder based framework, EEG2Vec, to learn generative-discriminative representations from EEG data. Experimental results on affective EEG recording datasets demonstrate that our model is suitable for unsupervised EEG modeling, classification of three distinct emotion categories (positive, neutral, negative) based on the latent representation achieves a robust performance of 68.49%, and generated synthetic EEG sequences resemble real EEG data inputs to particularly reconstruct low-frequency signal components. Our work advances areas where affective EEG representations can be useful in e.g., generating artificial (labeled) training data or alleviating manual feature extraction, and provide efficiency for memory constrained edge computing applications.

Keywords

Cite

@article{arxiv.2207.08002,
  title  = {EEG2Vec: Learning Affective EEG Representations via Variational Autoencoders},
  author = {David Bethge and Philipp Hallgarten and Tobias Grosse-Puppendahl and Mohamed Kari and Lewis L. Chuang and Ozan Özdenizci and Albrecht Schmidt},
  journal= {arXiv preprint arXiv:2207.08002},
  year   = {2022}
}

Comments

8 pages, 7 figures

R2 v1 2026-06-25T00:58:33.513Z