Human Emotion Classification based on EEG Signals Using Recurrent Neural Network And KNN

IF 0.3
Shashank Joshi, Falak Joshi
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引用次数: 1

Abstract

In human contact, emotion is very crucial. Attributes like words, voice intonation, facial expressions, and kinesics can all be used to portray one's feelings. However, brain-computer interface (BCI) devices have not yet reached the level required for emotion interpretation. With the rapid development of machine learning algorithms, dry electrode techniques, and different real-world applications of the brain-computer interface for normal individuals, emotion categorization from EEG data has recently gotten a lot of attention. Electroencephalogram (EEG) signals are a critical resource for these systems. The primary benefit of employing EEG signals is that they reflect true emotion and are easily resolved by computer systems. In this work, EEG signals associated with good, neutral, and negative emotions were identified using channel selection preprocessing. However, researchers had a limited grasp of the specifics of the link between various emotional states until now. To identify EEG signals, we used discrete wavelet transform and machine learning techniques such as recurrent neural network (RNN) and k-nearest neighbor (kNN) algorithm. Initially, the classifier methods were utilized for channel selection. As a result, final feature vectors were created by integrating the features of EEG segments from these channels. Using the RNN and kNN algorithms, the final feature vectors with connected positive, neutral, and negative emotions were categorized independently. The classification performance of both techniques is computed and compared. Using RNN and kNN, the average overall accuracies were 94.844 % and 93.438 %, respectively.
基于递归神经网络和KNN的脑电信号情感分类
在人际交往中,情感是至关重要的。文字、语音语调、面部表情和动作等属性都可以用来描绘一个人的感受。然而,脑机接口(BCI)设备尚未达到情感解释所需的水平。随着机器学习算法、干电极技术的快速发展以及正常人脑机接口在现实世界中的不同应用,基于脑电图数据的情绪分类得到了广泛的关注。脑电图(EEG)信号是这些系统的重要资源。使用脑电图信号的主要好处是它们反映了真实的情绪,并且很容易被计算机系统识别。在这项工作中,使用通道选择预处理识别与良好、中性和消极情绪相关的脑电图信号。然而,到目前为止,研究人员对各种情绪状态之间联系的细节掌握有限。为了识别EEG信号,我们使用了离散小波变换和机器学习技术,如循环神经网络(RNN)和k-最近邻(kNN)算法。最初,使用分类器方法进行信道选择。最终的特征向量是通过对这些通道的脑电信号片段的特征进行综合而得到的。使用RNN和kNN算法,对具有连接的积极、中性和消极情绪的最终特征向量进行独立分类。对两种方法的分类性能进行了计算和比较。使用RNN和kNN,平均整体准确率分别为94.844%和93.438%。
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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来源期刊
International Journal of Next-Generation Computing
International Journal of Next-Generation Computing COMPUTER SCIENCE, THEORY & METHODS-
自引率
66.70%
发文量
60
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