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EEG-based Emotion Classificationusing Deep Belief Networks
Key Lab. of Shanghai Education Commission forIntelligent Interaction and Cognitive Engineering
Among the approaches to emotion recognition, methods based on electroencephalogram (EEG) sig-nals are more reliable because of its high accuracy and objective evaluation compared to other external appearance such as facial expression and gesture. However due to the low signal to noise ratio (SNR), it is often very hard to analyze EEG signals ‘by hand’even for neurophysiologists. Recent developing deep learning in machine learning community allows au-tomated feature extraction and feature selection and eliminates the limitation of hand-crafted feature.
gamma frequency bands do exist. Second, we show that differential entropy (DE) features extracted from EEG data possess accurate and stable information for emotion classification. Finally, the paper com-pares the results between deep modals and shallow models like KNN, SVM and GELM. Moreover, DBN-HMM performs well when compared with the state-of-the-art classification methods.
Deep Belief Networks (DBN) is a probabilistic gen-erative model with deep architecture, which charac-terizes the input data distribution using hidden vari-ables. A DBN is constructed by stacking a predefined number of restricted Boltzmann machines (RBMs) on top of each other where the output from a lower-lev-el RBM is the input to a higher-level RBM.
The graphical depiction of DBN
Wei-Long Zheng, Jia-Yi Zhu, Yong Peng, and Bao-Liang Lu
FeatureExtraction
Raw Data
SVM
FeatureExtraction
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DBN
HMM
FeatureExtraction
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DBN
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FeatureExtraction
Raw Data
GELM
(c)
FeatureExtraction
Raw Data
KNN
(a)
Overview of the five setups for EEG-based emotion classification used in this work
Session K-2 Session K-1 Session K Session K+1 Session K+2
Hint of start
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Positive Emotion
Positive Emotion
Positive Emotion
Negative Emotion
Negative Emotion
Protocol of the EEG experiment
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There exist specific neural patterns in beta and gamma bands for positive and negative emotions
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Introduction
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Conclusion In this paper, we introduce recent advanced deep learning models to EEG-based emotion classifica-tion. The main contributions of this paper are as fol-lows: First, we find that neural signatures associated with positive and negative emotions in beta and
IEEE International Conference on Multimedia & Expo (ICME), 2014