Interpretable EEG Microstate Discovery via Variational Deep Embedding: A Systematic Architecture Search with Multi-Quadrant Evaluation
Saheed Faremi, Andrea Visentin, Luca Longo
TL;DR
This paper introduces Conv-VaDE, a deep generative model for EEG microstate analysis that enhances interpretability and stability through systematic architecture search and probabilistic clustering.
Contribution
It presents a novel convolutional variational embedding model that jointly learns topographic reconstruction and soft clustering, improving EEG microstate interpretability.
Findings
Depth L=4 networks perform best across configurations.
Best GEV achieved is 0.730 with K=4 clusters.
Architecture search is crucial for stable microstate discovery.
Abstract
EEG microstate analysis segments continuous brain electrical activity into brief, quasi-stable topographic configurations that reflect discrete functional brain states. Conventional approaches such as Modified K-Means operate directly in electrode space with hard assignment, offering no learned latent representation, no generative decoder, and no mechanism to decode latent configurations into verifiable scalp topographies, limiting both model transparency and interpretability. To address this, we present a Convolutional Variational Deep Embedding (Conv-VaDE) model that jointly learns topographic reconstruction and probabilistic soft clustering in a shared latent space. Conv-VaDE enables generative decoding of cluster prototypes into verifiable scalp topographies, replacing opaque hard partitioning with probabilistic soft assignment. A polarity invariance scheme and a four-dimensional…
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