Research of electroencephalography representational emotion recognition based on deep belief networks_Journal of Biomedical Engineering

Authors：

YANG Hao ,  ZHANG Junran , JIANG Xiaomei , LIU Fei

School of Electrical Engineering and Information, Sichuan University, Chengdu 610065, P.R.China;

Corresponding author：

ZHANG Junran, Email: zhangjunran@126.com

Keywords：

deep learning; deep belief network; electroencephalogram; emotional recognition

DOI：

10.7507/1001-5515.201706035

Video：

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In recent years, with the rapid development of machine learning techniques,the deep learning algorithm has been widely used in one-dimensional physiological signal processing. In this paper we used electroencephalography (EEG) signals based on deep belief network (DBN) model in open source frameworks of deep learning to identify emotional state (positive, negative and neutrals), then the results of DBN were compared with support vector machine (SVM). The EEG signals were collected from the subjects who were under different emotional stimuli, and DBN and SVM were adopted to identify the EEG signals with changes of different characteristics and different frequency bands. We found that the average accuracy of differential entropy (DE) feature by DBN is 89.12%±6.54%, which has a better performance than previous research based on the same data set. At the same time, the classification effects of DBN are better than the results from traditional SVM (the average classification accuracy of 84.2%±9.24%) and its accuracy and stability have a better trend. In three experiments with different time points, single subject can achieve the consistent results of classification by using DBN (the mean standard deviation is1.44%), and the experimental results show that the system has steady performance and good repeatability. According to our research, the characteristic of DE has a better classification result than other characteristics. Furthermore, the Beta band and the Gamma band in the emotional recognition model have higher classification accuracy. To sum up, the performances of classifiers have a promotion by using the deep learning algorithm, which has a reference for establishing a more accurate system of emotional recognition. Meanwhile, we can trace through the results of recognition to find out the brain regions and frequency band that are related to the emotions, which can help us to understand the emotional mechanism better. This study has a high academic value and practical significance, so further investigation still needs to be done.

Citation： YANG Hao, ZHANG Junran, JIANG Xiaomei, LIU Fei. Research of electroencephalography representational emotion recognition based on deep belief networks. Journal of Biomedical Engineering, 2018, 35(2): 182-190. doi: 10.7507/1001-5515.201706035 Copy

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18.	Hinton G, Deng L, Yu D, et al. Deep neural networks for acoustic modeling in speech recognition: The shared views of four research groups. IEEE Signal Process Mag, 2012, 29(6): 82-97.
19.	Li Kang, Li Xiaoyi, Zhang Yuan, et al. Affective state recognition from EEG with deep belief networks//Bioinformatics and biomedicine (BIBM), 2013 IEEE International Conference on. Shanghai, 2013: 305-310.
20.	Wang Dan, Shang Yi. Modeling physiological data with deep belief networks. International journal of information and education technology (IJIET), 2013, 3(5): 505-511.
21.	Ghayoumi M, Bansal A K. Emotion in robots using convolutional neural networks//International conference on social robotics, Springer International Publishing. Kansas City, 2016: 285-295.
22.	赵军圣, 庄光明, 王增桂. 极大似然估计方法介绍. 长春理工大学学报:自然科学版, 2010(6): 53-54.
23.	Zheng Weilong, Lu Baoliang. Investigating critical frequency bands and channels for EEG-Based emotion recognition with deep neural networks. IEEE Trans Auton Ment Dev, 2015, 7(3, SI): 162-175.
24.	Soleymani M, Pantic M, Pun T. Multimodal emotion recognition in response to videos. IEEE Transactions on Affective Computing, 2012, 3(2): 211-223.
25.	Ioffe S, Szegedy C. Batch normalization: Accelerating deep network training by reducing internal covariate shift. arXiv, 2015, arXiv: 1502.03167.
26.	Nair V, Hinton G E. Rectified linear units improve restricted Boltzmann machines//Proceedings of the 27th international conference on machine learning (ICML-10). Haifa, 2010: 807-814.
27.	Wang X, Fouhey D, Gupta A. Designing deep networks for surface normal estimation//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Boston, 2015: 539-547.
28.	Duan Ruonan, Zhu Jiayi, Lu Baoliang. Differential entropy feature for EEG-Based emotion classification//2013 6th International Ieee/Embs Conference On Neural Engineering (NER), 2013: 81-84.
29.	聂聃, 王晓韡, 段若男, 等. 基于脑电的情绪识别研究综述. 中国生物医学工程学报, 2012, 31(4): 595-606.
30.	Apez J W. A proposed mechanism of emotion. Archives of Neurology & Psychiatry, 1937, 38(4): 725-743.

1. Fletcher D, Scott M. Psychological stress in sports coaches: a review of concepts, research, and practice. J Sports Sci, 2010, 28(2): 127-137.
2. Sutherland M. Generating brain waves that pierce attention. 2005: 1-4. http://www.sutherlandsurvey.com/.
3. Krapohl D, Mcmanus B. An objective method for manually scoring polygraph data. Polygraph, 1999, 28(3): 209-222.
4. de Rubeis S, He Xin, Goldberg A P, et al. Synaptic, transcriptional and chromatin genes disrupted in autism. Nature, 2014, 515(7526): 209-215.
5. Hall G C, Szechtman H, Nahmias C. Enhanced salience and emotion recognition in autism: A PET study. American Journal of Psychiatry, 2003, 160(8): 1439-1441.
6. Knyazev G G, Slobodskoj-Plusnin J Y, Bocharov A V. Gender differences in implicit and explicit processing of emotional facial expressions as revealed by event-related theta synchronization. Emotion, 2010, 10(5): 678-687.
7. Sammler D, Grigutsch M, Fritz T, et al. Music and emotion: electrophysiological correlates of the processing of pleasant and unpleasant music. Psychophysiology, 2007, 44(2): 293-304.
8. Li Mu, Lu Baoliang. Emotion classification based on gamma-band EEG//2009 Annual international conference of the IEEE engineering in medicine and biology society, Minneapolis, 2009: 1323-1326.
9. Nie D, Wang X W, Shi L C, et al. EEG-based emotion recognition during watching movies//5th International IEEE/EMBS Conference on, Cancun, 2011: 667-670.
10. Wang Xiaowei, Nie Dan, Lu Baoliang. Emotional state classification from EEG data using machine learning approach. Neurocomputing, 2014, 129(SI): 94-106.
11. 蒋小梅, 张俊然, 陈富琴, 等. 基于 J48 决策树分类器的情绪识别与结果分析. 计算机工程与设计, 2017, 38(3): 761-767.
12. 苏建新. 基于脑电信号的情绪识别研究. 南京: 南京邮电大学, 2015.
13. Frantzidis C A, Bratsas C, Klados M A, et al. On the classification of emotional biosignals evoked while viewing affective pictures: an integrated data-mining-based approach for healthcare applications. IEEE Trans Inf Technol Biomed, 2010, 14(2): 309-318.
14. Bengio Y. Learning deep architectures for AI. Foundations and Trends in Machine Learning, 2009, 2(1): 1-127.
15. Braverman M. Poly-logarithmic independence fools bounded-depth booleancircuits. Commun ACM, 2011, 54(4): 108-115.
16. Le Q V. Building high-level features using large scale unsupervised learning//2013 IEEE international conference on acoustics, speech and signal processing (ICASSP), 2013: 8595-8598.
17. Krizhevsky A, Sutskever I, Hinton G E. Imagenet classification with deep convolutional neural networks//Advances in neural information processing systems. 2012: 1097-1105.
18. Hinton G, Deng L, Yu D, et al. Deep neural networks for acoustic modeling in speech recognition: The shared views of four research groups. IEEE Signal Process Mag, 2012, 29(6): 82-97.
19. Li Kang, Li Xiaoyi, Zhang Yuan, et al. Affective state recognition from EEG with deep belief networks//Bioinformatics and biomedicine (BIBM), 2013 IEEE International Conference on. Shanghai, 2013: 305-310.
20. Wang Dan, Shang Yi. Modeling physiological data with deep belief networks. International journal of information and education technology (IJIET), 2013, 3(5): 505-511.
21. Ghayoumi M, Bansal A K. Emotion in robots using convolutional neural networks//International conference on social robotics, Springer International Publishing. Kansas City, 2016: 285-295.
22. 赵军圣, 庄光明, 王增桂. 极大似然估计方法介绍. 长春理工大学学报:自然科学版, 2010(6): 53-54.
23. Zheng Weilong, Lu Baoliang. Investigating critical frequency bands and channels for EEG-Based emotion recognition with deep neural networks. IEEE Trans Auton Ment Dev, 2015, 7(3, SI): 162-175.
24. Soleymani M, Pantic M, Pun T. Multimodal emotion recognition in response to videos. IEEE Transactions on Affective Computing, 2012, 3(2): 211-223.
25. Ioffe S, Szegedy C. Batch normalization: Accelerating deep network training by reducing internal covariate shift. arXiv, 2015, arXiv: 1502.03167.
26. Nair V, Hinton G E. Rectified linear units improve restricted Boltzmann machines//Proceedings of the 27th international conference on machine learning (ICML-10). Haifa, 2010: 807-814.
27. Wang X, Fouhey D, Gupta A. Designing deep networks for surface normal estimation//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Boston, 2015: 539-547.
28. Duan Ruonan, Zhu Jiayi, Lu Baoliang. Differential entropy feature for EEG-Based emotion classification//2013 6th International Ieee/Embs Conference On Neural Engineering (NER), 2013: 81-84.
29. 聂聃, 王晓韡, 段若男, 等. 基于脑电的情绪识别研究综述. 中国生物医学工程学报, 2012, 31(4): 595-606.
30. Apez J W. A proposed mechanism of emotion. Archives of Neurology & Psychiatry, 1937, 38(4): 725-743.

Journal of Biomedical Engineering

Research of electroencephalography representational emotion recognition based on deep belief networks

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