Design of a Network Permutation Entropy and Its Applications for Chaotic Time Series and EEG Signals

Design of a Network Permutation Entropy and Its Applications for Chaotic Time Series and EEG Signals

Measuring the complexity of time series provides an important indicator for characteristic analysis of nonlinear systems. The permutation entropy (PE) is widely used, but it still needs to be modified. In this paper, the PE algorithm is improved by introducing the concept of the network, and the net...

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Bibliographic Details
Published in:Entropy (Basel, Switzerland) Vol. 21; no. 9; p. 849
Main Authors: Yan, Bo, He, Shaobo, Sun, Kehui
Format: Journal Article
Language:English
Published: Basel MDPI AG 30-08-2019
MDPI
Subjects:
Algorithms
chaotic system
Complexity
EEG signal
Electroencephalography
Entropy
Methods
network
Neural networks
Nonlinear systems
permutation entropy
Permutations
Probability distribution
Seizures
Signal processing
Systems analysis
Time series
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Summary:Measuring the complexity of time series provides an important indicator for characteristic analysis of nonlinear systems. The permutation entropy (PE) is widely used, but it still needs to be modified. In this paper, the PE algorithm is improved by introducing the concept of the network, and the network PE (NPE) is proposed. The connections are established based on both the patterns and weights of the reconstructed vectors. The complexity of different chaotic systems is analyzed. As with the PE algorithm, the NPE algorithm-based analysis results are also reliable for chaotic systems. Finally, the NPE is applied to estimate the complexity of EEG signals of normal healthy persons and epileptic patients. It is shown that the normal healthy persons have the largest NPE values, while the EEG signals of epileptic patients are lower during both seizure-free intervals and seizure activity. Hence, NPE could be used as an alternative to PE for the nonlinear characteristics of chaotic systems and EEG signal-based physiological and biomedical analysis.
Bibliography:These authors contributed equally to this work.
ISSN:1099-4300
1099-4300
DOI:10.3390/e21090849