ARGOUL, Françoise; GUILLET, Alexandre

Métadonnées

Afficher la notice complète

Licence d’utilisation du document

ARGOUL, Françoise
Laboratoire Ondes et Matière d'Aquitaine [LOMA]

GUILLET, Alexandre
Laboratoire Ondes et Matière d'Aquitaine [LOMA]

Langue

Document de travail - Pré-publication

Ce document a été publié dans

2023-10-26

Résumé en anglais

Physiological recordings contain a great deal of information about the underlying dynamics of life. The practical statistical treatment of these single-trial measurements is often hampered by the inadequacy of overly strong assumptions. Heisenberg's uncertainty principle allows for more parsimony, trading off statistical significance for localization. By decomposing signals into time-frequency atoms and recomposing them into local and flexible estimators, we propose a concise and expressive implementation of these fundamental concepts based on the choice of a geometric paradigm and two physical parameters. Starting from the spectrogram based on two fixed timescales and Gabor normal window, we then build its scale-invariant analogue, the scalogram based on two quality factors and Grossmann log-normal wavelet. These canonical estimators provide a minimal and flexible framework for single trial time-frequency statistics, which we apply to polysomnographic signals: EEG representations, coherence and mutual information between ECG-derived heart rate and respiration, and their spurious statistics.< Réduire

Mots clés en anglais

Time-frequency analysis

Log-normal wavelet

Uncertainty principle

Polysomnography

Physiological signals

Coherence

Statistical significance

Mutual information

Single trial time-frequency statistics

Métadonnées

Partager cette publication !

Licence d’utilisation du document

Uncertainty and information in physiological signals: explicit physical trade-off with log-normal wavelets

Langue

Ce document a été publié dans

Résumé en anglais

Mots clés en anglais

URI

Origine

Unités de recherche