Rules-Based and SVM-Q Methods With Multitapers and Convolution for Sleep EEG Stages Classification

Sleep EEG signals analysis is an approach that helps researchers identify and understand the different phenomena concealed within sleep EEG data. This research introduces a time-frequency analysis approach to untangle the parameters of the sleep stages classification from EEG data. This approach com...

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Bibliographic Details
Published inIEEE access Vol. 10; pp. 71299 - 71310
Main Authors Zapata, Ignacio A., Li, Yan, Wen, Peng
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Accuracy
Classifiers
Convolution
Electroencephalography
Electrooculography
Estimation
Feature extraction
Multitapers
Quadratic equations
Signal classification
Sleep
sleep EEG
sleep rules
sleep stages
spectra density estimation (SDE)
spectral estimation
support vector machine
Support vector machines
SVM-Q
Time-frequency analysis
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Summary:Sleep EEG signals analysis is an approach that helps researchers identify and understand the different phenomena concealed within sleep EEG data. This research introduces a time-frequency analysis approach to untangle the parameters of the sleep stages classification from EEG data. This approach computes the spectral estimation of a signal based on a set of controlled wavelets using a multitaper with convolution (MT&C) method. In this study, the MT&C methods is implemented to extract the features from a single sleep EEG data channel. Then two separated approaches are applied for sleep stage classification. The first one is based on the EEG waves characteristic definitions of sleep stages (named as Rules-based method) to directly classify each 30 second EEG segment after the feature extraction. The second approach uses a support vector machine with quadratic equation (SVM-Q) classifier to classify the sleep stages based on experts' scoring. The experimental results are evaluated, and the outcomes show an overall accuracy of 90% with an average sensitivity of 96.2% and an average specificity of 93.2% using an SVM-Q classifier and an 87.6% accuracy for the Rules-based method on healthy subjects. On the other hand, the accuracy on subjects with abnormal sleep EEG data is of 78.1% with the SVM-Q classifier and 73.4% with the Rules-based method.
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ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2022.3188286