基于动态微分熵和脑连接性特征的脑电情绪识别

IF 5 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE International Journal of Intelligent Systems Pub Date : 2022-12-02 DOI:10.1002/int.23096
Fa Zheng, Bin Hu, Xiangwei Zheng, Cun Ji, Ji Bian, Xiaomei Yu
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引用次数: 2

摘要

情绪识别已成为脑机接口和认知神经科学的研究热点。脑电图具有准确、客观、无创等优点。然而,现有的许多研究只关注于提取EEG信号的时域和频域特征,而没有利用动态时间变化和不同电极通道之间的位置关系。为了填补这一空白,我们使用名为DDELGCN的线性图卷积网络开发了基于动态差分熵和大脑连接特征的脑电情绪识别。首先,在传统差分熵特征的基础上,提取了表示频域特征和时域特征的动态差分熵。其次,通过计算Pearson相关系数、锁相值和传递熵来构建大脑连接矩阵,然后用于表示所有电极组合的连接特征。最后,定制并应用线性图卷积网络来聚合来自总电极组合的特征,然后对情绪状态进行分类,该网络由五层组成,即一个输入层、两个线性图卷积层、一个全连接层和一个softmax层。大量实验表明,在DEAP数据集上,效价和唤醒维度的准确率分别达到90.88%和91.13%,精度分别达到96.66%和97.02%。在SEED数据集上,准确率和精密度分别达到91.56%和97.38%。
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Dynamic differential entropy and brain connectivity features based EEG emotion recognition

Emotion recognition has become a research focus in the brain–computer interface and cognitive neuroscience. Electroencephalogram (EEG) is employed for its advantages as accurate, objective, and noninvasive nature. However, many existing research only focus on extracting the time and frequency domain features of the EEG signals while failing to utilize the dynamic temporal changes and the positional relationships between different electrode channels. To fill this gap, we develop the dynamic differential entropy and brain connectivity features based EEG emotion recognition using linear graph convolutional network named DDELGCN. First, the dynamic differential entropy feature which represents the frequency domain feature as well as time domain feature is extracted based on the traditional differential entropy feature. Second, brain connectivity matrices are constructed by calculating the Pearson correlation coefficient, phase-locked value and transfer entropy, and then are used to denote the connectivity features of all electrode combinations. Finally, a linear graph convolutional network is customized and applied to aggregate the features from total electrode combinations and then classifies the emotional states, which consists of five layers, namely, an input layer, two linear graph convolutional layers, a fully connected layer, and a softmax layer. Extensive experiments show that the accuracies in the valence and arousal dimensions reach 90.88% and 91.13%, and the precision reaches 96.66% and 97.02% on the DEAP dataset, respectively. On the SEED dataset, the accuracy and precision reach 91.56% and 97.38%, respectively.

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来源期刊
International Journal of Intelligent Systems
International Journal of Intelligent Systems 工程技术-计算机:人工智能
CiteScore
11.30
自引率
14.30%
发文量
304
审稿时长
9 months
期刊介绍: The International Journal of Intelligent Systems serves as a forum for individuals interested in tapping into the vast theories based on intelligent systems construction. With its peer-reviewed format, the journal explores several fascinating editorials written by today''s experts in the field. Because new developments are being introduced each day, there''s much to be learned — examination, analysis creation, information retrieval, man–computer interactions, and more. The International Journal of Intelligent Systems uses charts and illustrations to demonstrate these ground-breaking issues, and encourages readers to share their thoughts and experiences.
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