Abstract
Wavelet family and differential evolution are proposed for categorization of epilepsy cases based on electroencephalogram (EEG) signals. Discrete wavelet transform is widely used in feature extraction step because it efficiently works in this field, as confirmed by the results of previous studies. The feature selection step is used to minimize dimensionality by excluding irrelevant features. This step is conducted using differential evolution. This article presents an efficient model for EEG classification by considering feature extraction and selection. Seven different types of common wavelets were tested in our research work. These are Discrete Meyer (dmey), Reverse biorthogonal (rbio), Biorthogonal (bior), Daubechies (db), Symlets (sym), Coiflets (coif), and Haar (Haar). Several kinds of discrete wavelet transform are used to produce a wide variety of features. Afterwards, we use differential evolution to choose appropriate features that will achieve the best performance of signal classification. For classification step, we have used Bonn databases to build the classifiers and test their performance. The results prove the effectiveness of the proposed model.
Highlights
Brain–computer interface (BCI) is a direct channel of communication between brain and the computer,[1] and this contact is used by computer to control brain
We proposed a new approach based on a hybrid of wavelet family and differential evolution (DE) for recognition of epilepsy cases from EEG signals
We presented a new model to detect seizure depending on EEG binary classification
Summary
Brain–computer interface (BCI) is a direct channel of communication between brain and the computer,[1] and this contact is used by computer to control brain. The research started in the field of BCI in 1970s in the University of California, Los Angeles.[2] The focus was on artificial neural limbs that participate in applications, which aimed to restore defect in hearing, sight, or movement. The basic idea of BCI principle depends on four main steps. Getting the information or brain waves (signals). Electroencephalogram (EEG) processing by filtering signals from sources other than brain, and unwanted signals are produced either from vital sources, such as eye muscles
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