Abstract
The studies implemented with Electroencephalogram (EEG) signals are progressing very rapidly and brain computer interfaces (BCI) and disease determinations are carried out at certain success rates thanks to new methods developed in this field. The effective use of these signals, especially in disease detection, is very important in terms of both time and cost. Currently, in general, EEG studies are used in addition to conventional methods as well as deep learning networks that have recently achieved great success. The most important reason for this is that in conventional methods, increasing classification accuracy is based on too many human efforts as EEG is being processed, obtaining the features is the most important step. This stage is based on both the time-consuming and the investigation of many feature methods. Therefore, there is a need for methods that do not require human effort in this area and can learn the features themselves. Based on that, two-dimensional (2D) frequency-time scalograms were obtained in this study by applying Continuous Wavelet Transform to EEG records containing five different classes. Convolutional Neural Network structure was used to learn the properties of these scalogram images and the classification performance of the structure was compared with the studies in the literature. In order to compare the performance of the proposed method, the data set of the University of Bonn was used. The data set consists of five EEG records containing healthy and epilepsy disease which are labeled as A, B, C, D, and E. In the study, A-E and B-E data sets were classified as 99.50%, A-D and B-D data sets were classified as 100% in binary classifications, A-D-E data sets were 99.00% in triple classification, A-C-D-E data sets were 90.50%, B-C-D-E data sets were 91.50% in quaternary classification, and A-B-C-D-E data sets were in the fifth class classification with an accuracy of 93.60%.
Highlights
The brain, which is the center of all cognitive and sensory stimuli, controls the vital functions in the body
The stages of the method we proposed in this study are as follows: a) Frequency-time scalograms are obtained from raw EEG signals due to the success of deep learning networks in image processing area; b) Data sets are classified in Convolutional Neural Network (CNN) with different combinations
Frequency-time images obtained from EEG signals were evaluated in CNN structure
Summary
The brain, which is the center of all cognitive and sensory stimuli, controls the vital functions in the body This central unit has an excellent information processing function. These signals can be recorded using different methods These records, called electroencephalogram (EEG), contain a lot of information related to the work of the brain and other organs of the body [1,2,3]. The abnormal activity of these signals is used for disease detection and contains important information for monitoring the disease One of these diseases, which can be detected by EEG signals, is epilepsy [4]. From a clinical point of view, neurologists can examine the wave morphology of EEG signals
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