Bewaard in:
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| Formaat: | Recurso digital |
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| Gepubliceerd in: |
Zenodo
2026
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| Onderwerpen: | |
| Online toegang: | https://doi.org/10.5281/zenodo.19043484 |
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Inhoudsopgave:
- <p>This paper presents the first systematic application of Riemannian manifold analysis to the study of dynamical transitions in human EEG covariance structure. Using the affine-invariant metric on symmetric positive-definite matrices, we demonstrate that multichannel EEG covariance evolves through metastable geometric phases—discrete quasi-stable states separated by abrupt transitions—during sustained attention tasks. Across 20 subjects and 40 recording sessions from the publicly available COG-BCI dataset, plus an independent 60-minute driving simulation, we document heavy-tailed speed distributions (Fisher combined p = 7.32 × 10⁻8), 2.21-fold enrichment of dimensionality changes at transition boundaries (90% replication), and a dissociation between stochastic transition timing and deterministic regime identity consistent with Kramers escape theory. Geometric speed increases monotonically with working memory load and correlates modestly with reaction times, establishing functional relevance without circularity. These findings connect to recent geometric analyses of transformer neural networks, suggesting that metastable phase structure may be a convergent computational architecture across biological and artificial information-processing systems. All analyses use publicly available datasets and standard open-source tools.</p>