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A deep learning identification system for different epileptic seizure disease stages / Reeham Hussein Mahrous Ahmed Gabr ; Supervised Amr A. Sharawi

By: Contributor(s): Material type: TextTextLanguage: English Publication details: Cairo : Reeham Hussein Mahrous Ahmed Gabr , 2020Description: 79 P . : charts , facsmilies ; 30cmOther title:
  • نظام تعرف مبنى على التعلم العميق لمراحل نوبات الصرع المرضيه المختلفه [Added title page title]
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Dissertation note: Thesis (Ph.D.) - Cairo University - Faculty of Engineering - Department of Systems and Biomedical Engineering Summary: Epilepsy is a neurological disorder caused by abnormal discharge in the brain. The electroencephalogram plays an important role in monitoring brain activity in epilepsy diagnostic tasks. The EEG recording of epileptic patients shows abnormal activities including inter-ictal, pre-ictal, and ictal activity. Automatic detection of these abnormal activities aids the neurologists rather than using visual scanning. The selection of discriminative features from different EEG activities is the basis of the seizure detection method. Deep learning is introduced as an efficient approach in computer-aided medical diagnosis systems; it learns features automatically. In this study, a convolutional neural network (CNN) is employed to identify different epileptic seizure stages. We investigate CNN performance with different signal forms. First, time-domain signal is used as input to one dimensional 1-D CNN network. Second, the EEG signal is transformed to images using two different time-frequency domain transformation methods (Short-Time Fourier Transform (STFT) and the Continuous Wavelet Transform (CWT)), then the spectrogram and scalogram images produced for different epilepsy stages used as input to two dimensional CNN (Alexnet). The experiments are performed using CHB-MIT dataset which contains long time epilepsy recordings for different patients, the EEG signal from scalp left frontal-parietal bipolar channel (FP1-F7) only used. The performances of CNN using time domain signals and time-frequency domain images were compared. As the appearance of preictal activity is unknown, the experiment was done using a preictal labeled as 10 minutes before ictal onset once, then the experiment was repeated by using a preictal as 5 minutes before ictal. Experimental results suggest that the scalogram of the EEG signal increased the CNN classification accuracy to 97%. However, the spectrogram images achieved an accuracy of 73%, while the time domain signals achieved the lowest performance with an accuracy of 64%
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Thesis Thesis قاعة الرسائل الجامعية - الدور الاول المكتبة المركزبة الجديدة - جامعة القاهرة Cai01.13.03.Ph.D.2020.Re.D (Browse shelf(Opens below)) Not for loan 01010110082224000
CD - Rom CD - Rom مخـــزن الرســائل الجـــامعية - البدروم المكتبة المركزبة الجديدة - جامعة القاهرة Cai01.13.03.Ph.D.2020.Re.D (Browse shelf(Opens below)) 82224.CD Not for loan 01020110082224000

Thesis (Ph.D.) - Cairo University - Faculty of Engineering - Department of Systems and Biomedical Engineering

Epilepsy is a neurological disorder caused by abnormal discharge in the brain. The electroencephalogram plays an important role in monitoring brain activity in epilepsy diagnostic tasks. The EEG recording of epileptic patients shows abnormal activities including inter-ictal, pre-ictal, and ictal activity. Automatic detection of these abnormal activities aids the neurologists rather than using visual scanning. The selection of discriminative features from different EEG activities is the basis of the seizure detection method. Deep learning is introduced as an efficient approach in computer-aided medical diagnosis systems; it learns features automatically. In this study, a convolutional neural network (CNN) is employed to identify different epileptic seizure stages. We investigate CNN performance with different signal forms. First, time-domain signal is used as input to one dimensional 1-D CNN network. Second, the EEG signal is transformed to images using two different time-frequency domain transformation methods (Short-Time Fourier Transform (STFT) and the Continuous Wavelet Transform (CWT)), then the spectrogram and scalogram images produced for different epilepsy stages used as input to two dimensional CNN (Alexnet). The experiments are performed using CHB-MIT dataset which contains long time epilepsy recordings for different patients, the EEG signal from scalp left frontal-parietal bipolar channel (FP1-F7) only used. The performances of CNN using time domain signals and time-frequency domain images were compared. As the appearance of preictal activity is unknown, the experiment was done using a preictal labeled as 10 minutes before ictal onset once, then the experiment was repeated by using a preictal as 5 minutes before ictal. Experimental results suggest that the scalogram of the EEG signal increased the CNN classification accuracy to 97%. However, the spectrogram images achieved an accuracy of 73%, while the time domain signals achieved the lowest performance with an accuracy of 64%

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