Brain-Computer Interface of Motor Imagery Using ICA and Recurrent Neural Networks

2020 3rd International Conference on Computer and Informatics Engineering (IC2IE) Pub Date : 2020-09-15 DOI:10.1109/IC2IE50715.2020.9274681

Anita Safitri, E. C. Djamal, Fikri Nugraha

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引用次数: 2

Abstract

Brain-Computer Interface (BCI) is a device that can connect brain commands without the need for movement, gesture, or voice. Usually, BCI uses the Electroencephalogram (EEG) signal as an intermediate device. EEG signals need to be extracted into waves that represent the action in mind. In this study used Wavelet transformation to obtain the imagery motor component from the EEG signal. However, the problem also arises in the considerable channel redundancy in EEG signal recording. Therefore, it requires a signal reduction process. This paper proposed the problem using Independent Component Analysis (ICA). Then ICA components are features of Recurrent Neural Networks (RNN) to classify BCI information into four classes. The experimental results showed that using ICA improved accuracy by up to 99.06%, compared to Wavelet and RNN only, which is only 94.06%. We examined three optimization models, particularly Adam, AdaDelta, and AdaGrad. However, two optimization models provided the best recognition capabilities, i.e., AdaDelta, and AdaGrad.

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基于ICA和递归神经网络的运动图像脑机接口

脑机接口(BCI)是一种无需动作、手势或声音就能连接大脑指令的设备。脑机接口通常使用脑电图(EEG)信号作为中间设备。脑电图信号需要被提取成代表大脑动作的波。本研究采用小波变换从脑电信号中提取图像运动分量。然而，在脑电信号的记录中也存在着大量的信道冗余的问题。因此，需要进行信号降阶处理。本文利用独立分量分析(ICA)提出了该问题。然后将ICA分量作为递归神经网络(RNN)的特征，将脑机接口信息分为四类。实验结果表明，与仅使用小波和RNN的准确率仅为94.06%相比，使用ICA的准确率提高了99.06%。我们研究了三种优化模型，特别是Adam、AdaDelta和AdaGrad。然而，两种优化模型提供了最好的识别能力，即AdaDelta和AdaGrad。

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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2020 3rd International Conference on Computer and Informatics Engineering (IC2IE)

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