Computer Science

Computer Science ›› 2025, Vol. 52 ›› Issue (5): 122-127.doi: 10.11896/jsjkx.240200039

• Database & Big Data & Data Science • Previous Articles     Next Articles

Study on EEG Emotion Recognition Method Based on Self-supervised Graph Network

ZHANG Jiaxiang, PAN Min, ZHANG Rui   

  1. Medical Big Data Research Center,Northwest University,Xi'an 710127,China
  • Received:2024-02-06 Revised:2024-06-12 Online:2025-05-15 Published:2025-05-12
  • About author:ZHANG Jiaxiang,born in 1998,postgraduate.His main research interests include medical big data analytics and deep learning.
    ZHANG Rui,born in 1971,Ph.D,professor,Ph.D supervisor.Her main research interests include medical big data analytics,machine learning and neural computational modeling.
  • Supported by:
    National Natural Science Foundation of China(12071369,62006189),Natural Science Foundation of Shannxi Province,China(2021JQ-430, 2023-JC-QN-0028) and China Postdoctoral Science Foundation(2022M722580).

PDF (PC)

72

Abstract: EEG emotion recognition refers to the technology of identifying human emotional states by analyzing electroencephalogram (EEG) signals,which has wide application prospects in some fields such as medical health,and human-computer interaction.Currently,EEG-based emotion recognition frequently relies on machine learning or deep learning techniques to thoroughly train labeled EEG data and differentiate various emotional states.However,such methods require a lot of data annotation,which is time-consuming and labor-intensive.Meanwhile,research shows that the spatial structure information of EEG signals can reflect the interaction of brain areas related to different emotional states,which can help identify emotional characteristics.To this end,this paper proposes an EEG emotion recognition method based on self-supervised graph network.First,the meiosis method is used to preprocess the EEG signal.Then,a graph convolutional network is used to extract spatial structure information from EEG signals,and the network is trained through self-supervised tasks.Finally,the feasibility and effectiveness of the proposed method have been validated through numerical experiments using the public datasets SEED and SEED-IV.Numerical results show that the accuracy of emotion recognition is 95.16% and 80.23%,which is superior to current methods.

Key words: EEG, Emotion recognition, Meiosis, Self-supervised learning, Graph convolutional network

CLC Number: 

  • TP391
[1]DOLAN R J.Emotion,cognition,and behavior[J].Science,2002,298(5596):1191-1194.
[2]ROY Y,BANVILLE H,ALBUQUERQUE I,et al.Deep learning-based electroencephalography analysis:a systematic review[J].Journal of Neural Engineering,2019,16(5):051001.
[3]LIU Y,SOURINA O,NGUYEN M.Real-time EEG-based emotion recognition and its applications[J].Transactions on Computational Science XII:Special Issue on Cyberworlds,2011,6670:256-277.
[4]EKMAN P E,DAVIDSON R J.The nature of emotion:Fundamental questions[M].Oxford University Press,1994:62-65.
[5]AZCARATE A,HAGELOH F,VAN DE SANDEK,et al.Automatic facial emotion recognition[EB/OL]. https://www.semanticscholar.org/paper/Automatic-facial-emotion-recognition-Azcarate-Sande/15c11294ea3fe1c48d1b9cff0b06d74143ea264a.
[6]SCHULLER B,RIGOLL G,LANG M.Speech emotion recognition combining acoustic features and linguistic information in a hybrid support vector machine-belief network architecture[C]//2004 IEEE International Conference on Acoustics,Speech,and Signal Processing.IEEE,2004,1:1-577.
[7]ZHENG W L,LU B L.Investigating critical frequency bandsand channels for EEG-based emotion recognition with deep neural networks[J].IEEE Transactions on Autonomous Mental Development,2015,7(3):162-175.
[8]LI Y,CHEN J,LI F,et al.GMSS:Graph-based multi-task self-supervised learning for EEG emotion recognition[J].IEEE Transactions on Affective Computing,2022,14(3):2512-2525.
[9]WU F,SOUZA A,ZHANG T,et al.Simplifying graph convolutional networks[C]//International Conference on Machine Learning.PMLR,2019:6861-6871.
[10]ZHONG P,WANG D,MIAO C.EEG-based emotion recognition using regularized graph neural networks[J].IEEE Transactions on Affective Computing,2020,13(3):1290-1301.
[11]DUAN R N,ZHU J Y,LU B L.Differential entropy feature for EEG-based emotion classification[C]//2013 6th International IEEE/EMBS Conference on Neural Engineering (NER).IEEE,2013:81-84.
[12]NIE D,WANG X W,SHI L C,et al.EEG-based emotion recognition during watching movies[C]//2011 5th International IEEE/EMBS Conference on Neural Engineering.IEEE,2011:667-670.
[13]WU Z,PAN S,CHEN F,et al.A comprehensive survey ongraph neural networks[J].IEEE Transactions on Neural Networks and Learning Systems,2020,32(1):4-24.
[14]ZHAO L M,YAN X,LU B L.Plug-and-play domain adaptation for cross-subject EEG-based emotion recognition[C]//Procee-dings of the AAAI Conference on Artificial Intelligence.2021:863-870.
[15]KAN H,YU J,HUANG J,et al.Self-supervised group meiosis contrastive learning for EEG-based emotion recognition[J].Applied Intelligence,2023,53(22):27207-27225.
[16]HE K,FAN H,WU Y,et al.Momentum contrast for unsupervised visual representation learning[C]//Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition.2020:9729-9738.
[17]CHEN T,KORNBLITH S,NOROUZI M,et al.A simpleframework for contrastive learning of visual representations[C]//International Conference on Machine Learning.PMLR,2020:1597-1607.
[18]LI Y,WANG L,ZHENG W,et al.A novel bi-hemispheric discrepancy model for EEG emotion recognition[J].IEEE Transactions on Cognitive and Developmental Systems,2020,13(2):354-367.
[19]KHOSLA P,TETERWAK P,WANG C,et al.Supervised con-trastive learning[J].Advances in Neural Information Processing Systems,2020,33:18661-18673.
[20]SHEN X,LIU X,HU X,et al.Contrastive learning of subject-invariant EEG representations for cross-subject emotion recognition[J].IEEE Transactions on Affective Computing,2022,14(3):2496-2511.
[21]MOHSENVAND M N,IZADI M R,MAES P.Contrastive re-presentation learning for electroencephalogram classification[C]//Machine Learning for Health.PMLR,2020:238-253.
[1] HUANG Qian, SU Xinkai, LI Chang, WU Yirui. Hypergraph Convolutional Network with Multi-perspective Topology Refinement forSkeleton-based Action Recognition [J]. Computer Science, 2025, 52(5): 220-226.
[2] ZHANG Lu, DUAN Youxiang, LIU Juan, LU Yuxi. Chinese Geological Entity Relation Extraction Based on RoBERTa and Weighted Graph Convolutional Networks [J]. Computer Science, 2024, 51(8): 297-303.
[3] YUAN Lining, FENG Wengang, LIU Zhao. Multi-channel Graph Convolutional Networks Enhanced by Label Propagation Algorithm [J]. Computer Science, 2024, 51(8): 304-312.
[4] HAN Bing, DENG Lixiang, ZHENG Yi, REN Shuang. Survey of 3D Point Clouds Upsampling Methods [J]. Computer Science, 2024, 51(7): 167-196.
[5] ZHANG Xiaoxi, LI Dongxi. Cancer Subtype Prediction Based on Similar Network Fusion Algorithm [J]. Computer Science, 2024, 51(6A): 230500006-7.
[6] HOU Lei, LIU Jinhuan, YU Xu, DU Junwei. Review of Graph Neural Networks [J]. Computer Science, 2024, 51(6): 282-298.
[7] LI Yilin, SUN Chengsheng, LUO Lin, JU Shenggen. Aspect-based Sentiment Classification for Word Information Enhancement Based on Sentence Information [J]. Computer Science, 2024, 51(6): 299-308.
[8] CHEN Wenzhong, CHEN Hongmei, ZHOU Lihua, FANG Yuan. Time-aware Pre-training Method for Sequence Recommendation [J]. Computer Science, 2024, 51(5): 45-53.
[9] YUAN Rong, PENG Lilan, LI Tianrui, LI Chongshou. Traffic Flow Prediction Model Based on Dual Prior-adaptive Graph Neural ODE Network [J]. Computer Science, 2024, 51(4): 151-157.
[10] ZHANG Jiahao, ZHANG Zhaohui, YAN Qi, WANG Pengwei. Speech Emotion Recognition Based on Voice Rhythm Differences [J]. Computer Science, 2024, 51(4): 262-269.
[11] ZHANG Mingdao, ZHOU Xin, WU Xiaohong, QING Linbo, HE Xiaohai. Unified Fake News Detection Based on Semantic Expansion and HDGCN [J]. Computer Science, 2024, 51(4): 299-306.
[12] YUAN Jing, XIA Ying. Vehicle Trajectory Prediction Based on Spatial-Temporal Graph Attention Convolutional Network [J]. Computer Science, 2024, 51(12): 157-165.
[13] ZHAO Ruonan, LI Duo, SONG Jiangling, ZHANG Rui. Automatic Sleep Staging Based on Multimodal Data and Fusion Deep Network [J]. Computer Science, 2024, 51(11A): 231100160-6.
[14] YANG Yufan, YUAN Liming, WANG Ke, LI Hongyi, LI Yixuan, YAO Yujia, WANG Jingyi. Grading Model for Diabetic Retinopathy Based on Graph Convolutional Network [J]. Computer Science, 2024, 51(11A): 231000042-5.
[15] LI Zhengping, LI Hanwen, WANG Lijun. High-generalization Ability EEG Emotion Recognition Model with Differential Entropy [J]. Computer Science, 2024, 51(11A): 231200066-7.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
渝ICP备16013121号-4
Add:18# Honghu West Rd., Yubei ,Chongqing,China    Post Code: 401121
Tel: 023-63500828/023-67039612/023-67039623
E-mail: jsjkx12@163.com
Powered by Beijing Magtech Co., Ltd.