Revealing critical channels and frequency bands for emotion recognition from EEG with deep belief network

Wei-Long Zheng, Hao-Tian Guo, Bao-Liang Lu
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引用次数: 49

Abstract

For EEG-based emotion recognition tasks, there are many irrelevant channel signals contained in multichannel EEG data, which may cause noise and degrade the performance of emotion recognition systems. In order to tackle this problem, we propose a novel deep belief network (DBN) based method for examining critical channels and frequency bands in this paper. First, we design an emotion experiment and collect EEG data while subjects are watching emotional film clips. Then we train DBN for recognizing three emotions (positive, neutral, and negative) with extracted differential entropy features as input and compare DBN with other shallow models such as KNN, LR, and SVM. The experiment results show that DBN achieves the best average accuracy of 86.08%. We further explore critical channels and frequency bands by examining the weight distribution learned by DBN, which is different from the existing work. We identify four profiles with 4, 6, 9 and 12 channels, which achieve recognition accuracies of 82.88%, 85.03%, 84.02%, 86.65%, respectively, using SVM.
揭示了基于深度信念网络的脑电情感识别的关键通道和频带
对于基于脑电图的情绪识别任务,多通道脑电图数据中含有许多不相关的通道信号,这些信号可能会产生噪声,降低情绪识别系统的性能。为了解决这一问题,本文提出了一种基于深度信念网络(DBN)的关键信道和关键频段检测方法。首先,我们设计了一个情绪实验,在被试观看情绪电影片段的同时采集EEG数据。然后,我们以提取的微分熵特征作为输入,训练DBN识别三种情绪(积极、中性和消极),并将DBN与其他浅模型(如KNN、LR和SVM)进行比较。实验结果表明,DBN的平均准确率达到了86.08%。我们通过检查DBN学习到的权重分布,进一步探索关键信道和频段,这与现有工作不同。采用支持向量机对4、6、9、12个通道的4个剖面进行了识别,识别准确率分别为82.88%、85.03%、84.02%、86.65%。
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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