Detection and classification of epilepsy using hybrid convolutional neural network

A. Sabarivani, R. Ramadevi
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引用次数: 1

Abstract

In recent years, more than 50 million people have been affected by the epilepsy, neurological disorder diseases. To monitor the situation of the epilepsy patient requires experienced and skilled person. In order to overcome these issues, autonomous detection of electroencephalogram (EEG) signal by deep learning model has evolved. Convolutional neural network (CNN) is one of the sub-category of neural network and widely used in the various field such as weather forecasting, signal processing and medical applications. In this article, the University of California Irvine (UCI) respiratory EEG signals are used to analyse the proposed hybrid CNN and results are compared to the pre-trained GoogleNet Network. EEG signals are initially converted into three different forms such as scalogram, spectrogram and time domain images and classification of images are carried out by the pre-trained GoogleNet network results in an accuracy of 85%. Then time domain images are combined with spectrogram and scalogram EEG signal separately and detection has been carried out by the CNN. It is found that the CNN network yields an accuracy of 92% which was higher than the pre-trained GoogleNet. To enhance the classification accuracy further, scalogram, spectrogram and time domain images are combined as single input images and applied to the CNN network and it results with the accuracy of 98%. The performance metrics such as Sensitivity, Specificity, F1 Score, Precision and misclassification rate of GoogleNet and proposed hybrid CNN networks are evaluated. It is observed from the result that proposed CNN results less than 10% misclassification rate, whereas for GoogleNet it was more than 20%. Similarly, the precision value of GoogleNet and proposed CNN networks are 82% and 93%, respectively.
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基于混合卷积神经网络的癫痫检测与分类
近年来,有超过5000万人受到癫痫等神经紊乱疾病的影响。监测癫痫患者的情况需要有经验和熟练的人员。为了克服这些问题,发展了基于深度学习的脑电图信号自主检测模型。卷积神经网络(Convolutional neural network, CNN)是神经网络的一个分支,广泛应用于天气预报、信号处理、医疗等各个领域。在本文中,使用加州大学欧文分校(UCI)的呼吸EEG信号来分析所提出的混合CNN,并将结果与预训练的GoogleNet网络进行比较。首先将脑电信号转换成尺度图、频谱图和时域图像三种不同的形式,利用预先训练好的GoogleNet网络对图像进行分类,准确率达到85%。然后将时域图像分别与脑电信号的谱图和尺度图相结合,利用CNN进行检测。研究发现,CNN网络的准确率为92%,高于预训练的GoogleNet。为了进一步提高分类精度,将尺度图、谱图和时域图像合并为单输入图像,应用到CNN网络中,准确率达到98%。对GoogleNet和混合CNN网络的灵敏度、特异性、F1评分、精度和误分类率等性能指标进行了评估。从结果中可以观察到,提出的CNN结果的误分类率小于10%,而GoogleNet的误分类率大于20%。同样,GoogleNet和提出的CNN网络的精度值分别为82%和93%。
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