AUTOMATED CLASSIFICATION OF AUTISM SPECTRUM DISORDER USING EEG SIGNALS AND CONVOLUTIONAL NEURAL NETWORKS

IF 0.6 Q4 ENGINEERING, BIOMEDICAL Biomedical Engineering: Applications, Basis and Communications Pub Date : 2022-03-16 DOI:10.4015/s101623722250020x

Qaysar Mohi ud Din, A. Jayanthy

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引用次数: 1

Abstract

Children suffering from Autism Spectrum Disorder (ASD) have impaired social communication, interaction and restricted and repetitive behaviors. ASD is caused by abnormal brain developments which give rise to the behavioral characteristics associated with ASD. The clinical diagnosis of ASD is performed on the basis of behavioral assessment and it causes a time delay in early intervention, as there is a time gap between abnormal brain developments and associated behavioral characteristics. Electroencephalography (EEG) is a technique which measures the electrical activity produced by the brain and it has been used to detect several neurological disorders. Studies have shown that there is a variation in the EEG signals of a normal subject and EEG signals of ASD subjects. In this study, we obtained scalograms of EEG signals by using Continuous Wavelet Transform (CWT). Pre-trained deep Convolutional Neural Networks (CNNs) such as GoogLeNet, AlexNet, MobileNet and SqueezeNet were used for extracting the features from scalograms and classification of obtained scalograms from EEG signals of normal and ASD subjects. We also used Support Vector Machine (SVM) algorithm and Relevance Vector Machine (RVM) for classification of the features extracted by the deep CNNs. The GoogLeNet, AlexNet, MobileNet and SqueezeNet deep CNNs achieved a validation accuracy of 75%, 75.84%, 79.45% and 82.98% in classifying the scalograms generated from EEG signals. The SVM achieved an accuracy of 71.6%, 74.76%, 70.70% and 81.47% using GoogleNet, Mobilenet, AlexNet and SqueezeNet for scalogram feature extraction. The RVM achieved an accuracy of 65.5%, 69.9%, 65.3% and 72.59% when used for classification using the features generated from GoogLeNet, AlexNet, MobileNet and SqueezeNet.The SqueezeNet deep CNN performed better than GoogLeNet, AlexNet and MobileNet for classification of the EEG scalograms. The feature extraction using SqueezeNet also resulted in better classification accuracy obtained by SVM and RVM. The results indicate that pre-trained models can be used for classifying the ASD using scalograms of the EEG signals.

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利用脑电图信号和卷积神经网络对自闭症谱系障碍进行自动分类

患有自闭症谱系障碍(ASD)的儿童在社交沟通、互动以及限制和重复行为方面存在障碍。ASD是由异常的大脑发育引起的，这些发育产生了与ASD相关的行为特征。ASD的临床诊断是在行为评估的基础上进行的，由于大脑发育异常与相关行为特征之间存在时间间隔，因此早期干预会出现时间延迟。脑电图(EEG)是一种测量大脑产生的电活动的技术，它已被用于检测几种神经系统疾病。研究表明，正常受试者的脑电图信号与ASD受试者的脑电图信号存在差异。在本研究中，我们利用连续小波变换(CWT)得到脑电信号的尺度图。使用GoogLeNet、AlexNet、MobileNet和SqueezeNet等预训练深度卷积神经网络(cnn)对正常和ASD受试者的脑电信号进行尺度图特征提取，并对得到的尺度图进行分类。我们还使用支持向量机(SVM)算法和相关向量机(RVM)算法对深度cnn提取的特征进行分类。GoogLeNet、AlexNet、MobileNet和SqueezeNet深度cnn对脑电信号生成的尺度图进行分类，验证准确率分别为75%、75.84%、79.45%和82.98%。使用GoogleNet、Mobilenet、AlexNet和SqueezeNet进行尺度图特征提取，SVM的准确率分别为71.6%、74.76%、70.70%和81.47%。使用GoogLeNet、AlexNet、MobileNet和SqueezeNet生成的特征进行分类时，RVM的准确率分别为65.5%、69.9%、65.3%和72.59%。在脑电尺度图分类方面，SqueezeNet深度CNN的表现优于GoogLeNet、AlexNet和MobileNet。使用SqueezeNet进行特征提取后，SVM和RVM的分类准确率也有所提高。结果表明，预先训练的模型可以利用脑电信号的尺度图对ASD进行分类。

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来源期刊

Biomedical Engineering: Applications, Basis and Communications Biochemistry, Genetics and Molecular Biology-Biophysics

CiteScore

1.50

自引率

11.10%

发文量

审稿时长

4 months

期刊介绍： Biomedical Engineering: Applications, Basis and Communications is an international, interdisciplinary journal aiming at publishing up-to-date contributions on original clinical and basic research in the biomedical engineering. Research of biomedical engineering has grown tremendously in the past few decades. Meanwhile, several outstanding journals in the field have emerged, with different emphases and objectives. We hope this journal will serve as a new forum for both scientists and clinicians to share their ideas and the results of their studies. Biomedical Engineering: Applications, Basis and Communications explores all facets of biomedical engineering, with emphasis on both the clinical and scientific aspects of the study. It covers the fields of bioelectronics, biomaterials, biomechanics, bioinformatics, nano-biological sciences and clinical engineering. The journal fulfils this aim by publishing regular research / clinical articles, short communications, technical notes and review papers. Papers from both basic research and clinical investigations will be considered.