Motor imagery EEG classification using feedforward neural network

Applied Medical Informaticvs Pub Date : 2021-01-01 DOI:10.33039/AMI.2021.04.007

T. Majoros, S. Oniga, Yu Xie

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引用次数: 1

Abstract

Electroencephalography (EEG) is a complex voltage signal of the brain and its correct interpretation requires years of training. Modern machine- learning methods help us to extract information from EEG recordings and therefore several brain-computer interface (BCI) systems use them in clinical applications. By processing the publicly available PhysioNet EEG dataset, we extracted information that could be used for training feedforward neural network to classify three types of activities performed by 109 volunteers. While volunteers were performing different activities, a BCI2000 system was recording their EEG signals from 64 electrodes. We used motor imagery runs where a target appeared on either the top or the bottom of a screen. The subject was instructed to imagine opening and closing either both his/her fists (if the target is on top) or both his/her feet (if the target is on the bottom) until the target disappears from the screen. We used the EEGLAB Matlab toolbox for EEG signal processing and applied several feature extraction techniques. Then we evaluated the classification performance of feedforward, multilayer perceptron (MLP) networks with different structures (number of layers, number of neurons). Achieved accuracy score for test data was 71.5%.

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前馈神经网络的运动意象脑电分类

脑电图(EEG)是一种复杂的大脑电压信号，其正确解释需要多年的训练。现代机器学习方法帮助我们从脑电图记录中提取信息，因此一些脑机接口(BCI)系统在临床应用中使用它们。通过对公开的PhysioNet EEG数据集进行处理，我们提取了可用于训练前馈神经网络的信息，对109名志愿者的三种活动进行分类。当志愿者进行不同的活动时，BCI2000系统记录了来自64个电极的脑电图信号。我们使用运动图像运行，目标出现在屏幕的顶部或底部。受试者被指示想象打开和关闭他/她的拳头(如果目标在上面)或他/她的脚(如果目标在下面)，直到目标从屏幕上消失。我们使用EEGLAB Matlab工具箱对脑电信号进行处理，并应用了几种特征提取技术。然后，我们评估了具有不同结构(层数、神经元数)的前馈多层感知器(MLP)网络的分类性能。测试数据的准确度得分为71.5%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Applied Medical Informaticvs

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