Characterization of time dynamical evolution of electroencephalographic epileptic records

Since traditional electrical brain signal analysis is mostly qualitative, the development of new quantitative methods is crucial for restricting the subjectivity in the study of brain signals. These methods are particularly fruitful when they are strongly correlated with intuitive physical concepts...

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Detalles Bibliográficos
Autores principales: Rosso, O.A., Mairal, M.L.
Formato: JOUR
Materias:
EEG
Epileptic seizures
Nonlinear dynamics metrics tools
Signal entropy
Time-frequency signal analysis
Wavelet analysis
Brain
Chaos theory
Characterization
Electrodes
Entropy
Lyapunov methods
Neurology
Nonlinear systems
Time series analysis
Electroencephalography
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_03784371_v312_n3-4_p469_Rosso
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_03784371_v312_n3-4_p469_Rosso
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spelling todo:paper_03784371_v312_n3-4_p469_Rosso2023-10-03T15:32:36Z Characterization of time dynamical evolution of electroencephalographic epileptic records Rosso, O.A. Mairal, M.L. EEG Epileptic seizures Nonlinear dynamics metrics tools Signal entropy Time-frequency signal analysis Wavelet analysis Brain Chaos theory Characterization Electrodes Entropy Lyapunov methods Neurology Nonlinear systems Time series analysis Signal entropy Electroencephalography Since traditional electrical brain signal analysis is mostly qualitative, the development of new quantitative methods is crucial for restricting the subjectivity in the study of brain signals. These methods are particularly fruitful when they are strongly correlated with intuitive physical concepts that allow a better understanding of the brain dynamics. The processing of information by the brain is reflected in dynamical changes of the electrical activity in time, frequency, and space. Therefore, the concomitant studies require methods capable of describing the qualitative variation of the signal in both time and frequency. The entropy defined from the wavelet functions is a measure of the order/disorder degree present in a time series. In consequence, this entropy evaluates over EEG time series gives information about the underlying dynamical process in the brain, more specifically of the synchrony of the group cells involved in the different neural responses. The total wavelet entropy results independent of the signal energy and becomes a good tool for detecting dynamical changes in the system behavior. In addition the total wavelet entropy has advantages over the Lyapunov exponents, because it is parameter free and independent of the stationarity of the time series. In this work we compared the results of the time evolution of the chaoticity (Lyapunov exponent as a function of time) with the corresponding time evolution of the total wavelet entropy in two different EEG records, one provide by depth electrodes and other by scalp ones. © 2002 Published by Elsevier Science B.V. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_03784371_v312_n3-4_p469_Rosso
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic EEG
Epileptic seizures
Nonlinear dynamics metrics tools
Signal entropy
Time-frequency signal analysis
Wavelet analysis
Brain
Chaos theory
Characterization
Electrodes
Entropy
Lyapunov methods
Neurology
Nonlinear systems
Time series analysis
Signal entropy
Electroencephalography
spellingShingle EEG
Epileptic seizures
Nonlinear dynamics metrics tools
Signal entropy
Time-frequency signal analysis
Wavelet analysis
Brain
Chaos theory
Characterization
Electrodes
Entropy
Lyapunov methods
Neurology
Nonlinear systems
Time series analysis
Signal entropy
Electroencephalography
Rosso, O.A.
Mairal, M.L.
Characterization of time dynamical evolution of electroencephalographic epileptic records
topic_facet EEG
Epileptic seizures
Nonlinear dynamics metrics tools
Signal entropy
Time-frequency signal analysis
Wavelet analysis
Brain
Chaos theory
Characterization
Electrodes
Entropy
Lyapunov methods
Neurology
Nonlinear systems
Time series analysis
Signal entropy
Electroencephalography
description Since traditional electrical brain signal analysis is mostly qualitative, the development of new quantitative methods is crucial for restricting the subjectivity in the study of brain signals. These methods are particularly fruitful when they are strongly correlated with intuitive physical concepts that allow a better understanding of the brain dynamics. The processing of information by the brain is reflected in dynamical changes of the electrical activity in time, frequency, and space. Therefore, the concomitant studies require methods capable of describing the qualitative variation of the signal in both time and frequency. The entropy defined from the wavelet functions is a measure of the order/disorder degree present in a time series. In consequence, this entropy evaluates over EEG time series gives information about the underlying dynamical process in the brain, more specifically of the synchrony of the group cells involved in the different neural responses. The total wavelet entropy results independent of the signal energy and becomes a good tool for detecting dynamical changes in the system behavior. In addition the total wavelet entropy has advantages over the Lyapunov exponents, because it is parameter free and independent of the stationarity of the time series. In this work we compared the results of the time evolution of the chaoticity (Lyapunov exponent as a function of time) with the corresponding time evolution of the total wavelet entropy in two different EEG records, one provide by depth electrodes and other by scalp ones. © 2002 Published by Elsevier Science B.V.
format JOUR
author Rosso, O.A.
Mairal, M.L.
author_facet Rosso, O.A.
Mairal, M.L.
author_sort Rosso, O.A.
title Characterization of time dynamical evolution of electroencephalographic epileptic records
title_short Characterization of time dynamical evolution of electroencephalographic epileptic records
title_full Characterization of time dynamical evolution of electroencephalographic epileptic records
title_fullStr Characterization of time dynamical evolution of electroencephalographic epileptic records
title_full_unstemmed Characterization of time dynamical evolution of electroencephalographic epileptic records
title_sort characterization of time dynamical evolution of electroencephalographic epileptic records
url http://hdl.handle.net/20.500.12110/paper_03784371_v312_n3-4_p469_Rosso
work_keys_str_mv AT rossooa characterizationoftimedynamicalevolutionofelectroencephalographicepilepticrecords
AT mairalml characterizationoftimedynamicalevolutionofelectroencephalographicepilepticrecords
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