El CRAI romandrà tancat del 24 de desembre de 2025 al 6 de gener de 2026. La validació de documents es reprendrà a partir del 7 de gener de 2026.
El CRAI permanecerá cerrado del 24 de diciembre de 2025 al 6 de enero de 2026. La validación de documentos se reanudará a partir del 7 de enero de 2026.
From 2025-12-24 to 2026-01-06, the CRAI remain closed and the documents will be validated from 2026-01-07.
 
Miniatura

Fitxers

tfg_di_croce_luca_eric.pdf (4.07 MB)
codi.zip (2.14 MB)

Tipus de document

Treball de fi de grau

Data de publicació

2023-06-13
Si us plau utilitzeu sempre aquest identificador per citar o enllaçar aquest document: https://hdl.handle.net/2445/200513

How do our brainwaves perceive the passage of time? Quantifying neural correlates of time during a rhythm performance task

Títol de la revista

Autors

Director/Tutor

ISSN de la revista

Títol del volum

Recurs relacionat

Resum

[en] The aim of this project is to establish a methodology to quantify the extent to which different brainwave signatures vary in their past data retention, and to determine how other factors interact with these variations, using previously obtained EEG recordings. To achieve this, we quantified the amount of past values that strongly influence future values for each brainwave signature throughout different EEG time series. Specifically, we calculated the number of lags required for a univariate autoregressive computational model to predict a set of brainwave time-series with an error (RMSE) below a preset threshold. In this fashion, we could establish that a similar number of lags were required based on the brainwave signatures (alpha, beta, gamma, or unfiltered) throughout the different conditions of activities and the different EEG sets, with the number of lags required being around 3, 4, and 6 for alpha, beta, and gamma brainwaves, respectively, when trying to achieve a minimum RMSE value of 0.001. This covariation is displayed again when using a different sets of threshold RMSE values, with gamma consistently having a greater dependency to past data, and alpha a lesser one. Our results indicate that brainwave signatures that are more related to active states can use past data for a longer period of time than brainwave signatures related to relaxed states. Furthermore, they suggest that active-state brainwaves show a more dilated time perception than their relaxed counterparts. In future studies, this methodology may help to establish a technique to objectively analyze time perception variation through EEG readings.

Descripció

Treballs Finals de Grau d'Enginyeria Informàtica, Facultat de Matemàtiques, Universitat de Barcelona, Any: 2023, Director: Ignasi Cos Aguilera

Matèries

Electroencefalografia, Percepció del temps, Programari, Treballs de fi de grau, Processament de dades, Neurociència cognitiva

Matèries (anglès)

Electroencephalography, Time perception, Computer software, Data processing, Cognitive neuroscience, Bachelor's theses

Citació

Col·leccions

Treballs Finals de Grau (TFG) - Enginyeria Informàtica

Citació

DI CROCE, Luca eric. How do our brainwaves perceive the passage of time? Quantifying neural correlates of time during a rhythm performance task. [consulta: 27 de desembre de 2025]. [Disponible a: https://hdl.handle.net/2445/200513]

Exportar metadades

JSON - METS

Compartir registre