Improved multiscale permutation entropy for biomedical signal analysis: Interpretation and application to electroencephalogram recordings

•Permutation entropy (PE) is a broadly used algorithm to measure the complexity of signals.•Multiscale PE (MPE) is based on assessing the PE for a number of coarse-grained sequences representing temporal scales.•To increase the stability and reliability of MPE, improved MPE (IMPE) is proposed.•Sever...

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Vydané v:Biomedical signal processing and control Ročník 23; s. 28 - 41
Hlavní autori: Azami, Hamed, Escudero, Javier
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier Ltd 01.01.2016
Predmet:
Biomedical signal analysis
Complexity
Electroencephalogram
Multiscale permutation entropy
Non-linear analysis
Signal regularity
Biomedical signal analysis
Multiscale permutation entropy
Electroencephalogram
Signal regularity
Non-linear analysis
Complexity
ISSN:1746-8094
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Popis
Shrnutí:•Permutation entropy (PE) is a broadly used algorithm to measure the complexity of signals.•Multiscale PE (MPE) is based on assessing the PE for a number of coarse-grained sequences representing temporal scales.•To increase the stability and reliability of MPE, improved MPE (IMPE) is proposed.•Several signal processing concepts are used to show the ability of IMPE.•We also apply MPE and IMPE for real publicly available electroencephalogram (EEG) signals. Permutation entropy (PE) is a well-known and fast method extensively used in many physiological signal processing applications to measure the irregularity of time series. Multiscale PE (MPE) is based on assessing the PE for a number of coarse-grained sequences representing temporal scales. However, the stability of the conventional MPE may be compromised for short time series. Here, we propose an improved MPE (IMPE) to reduce the variability of entropy measures over long temporal scales, leading to more reliable and stable results. We gain insight into the dependency of MPE and IMPE on several straightforward signal processing concepts which appear in biomedical activity via a set of synthetic signals. We also apply these techniques to real biomedical signals via publicly available electroencephalogram (EEG) recordings acquired with eyes open and closed and to ictal and non-ictal intracranial EEGs. We conclude that IMPE improves the reliability of the entropy estimations in comparison with the traditional MPE and that it is a promising technique to characterize physiological changes affecting several temporal scales. We provide the source codes of IMPE and the synthetic data in the public domain.
ISSN:1746-8094
DOI:10.1016/j.bspc.2015.08.004