5,003 research outputs found
An Automated System for Epilepsy Detection using EEG Brain Signals based on Deep Learning Approach
Epilepsy is a neurological disorder and for its detection, encephalography
(EEG) is a commonly used clinical approach. Manual inspection of EEG brain
signals is a time-consuming and laborious process, which puts heavy burden on
neurologists and affects their performance. Several automatic techniques have
been proposed using traditional approaches to assist neurologists in detecting
binary epilepsy scenarios e.g. seizure vs. non-seizure or normal vs. ictal.
These methods do not perform well when classifying ternary case e.g. ictal vs.
normal vs. inter-ictal; the maximum accuracy for this case by the
state-of-the-art-methods is 97+-1%. To overcome this problem, we propose a
system based on deep learning, which is an ensemble of pyramidal
one-dimensional convolutional neural network (P-1D-CNN) models. In a CNN model,
the bottleneck is the large number of learnable parameters. P-1D-CNN works on
the concept of refinement approach and it results in 60% fewer parameters
compared to traditional CNN models. Further to overcome the limitations of
small amount of data, we proposed augmentation schemes for learning P-1D-CNN
model. In almost all the cases concerning epilepsy detection, the proposed
system gives an accuracy of 99.1+-0.9% on the University of Bonn dataset.Comment: 18 page
Convolutional Neural Networks for Epileptic Seizure Prediction
Epilepsy is the most common neurological disorder and an accurate forecast of
seizures would help to overcome the patient's uncertainty and helplessness. In
this contribution, we present and discuss a novel methodology for the
classification of intracranial electroencephalography (iEEG) for seizure
prediction. Contrary to previous approaches, we categorically refrain from an
extraction of hand-crafted features and use a convolutional neural network
(CNN) topology instead for both the determination of suitable signal
characteristics and the binary classification of preictal and interictal
segments. Three different models have been evaluated on public datasets with
long-term recordings from four dogs and three patients. Overall, our findings
demonstrate the general applicability. In this work we discuss the strengths
and limitations of our methodology.Comment: accepted for MLESP 201
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