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Multi-Source Domain Transfer Discriminative Dictionary Learning Modeling for Electroencephalogram-Based Emotion Recognition

Xiaoqing GuSchool of Computer Science and Artificial Intelligence, Changzhou University, Changzhou, ChinaWeiwei CaiSchool of Logistics and Transportation, Central South University of Forestry and Technology, Changsha, ChinaMing GaoCollege of Sports Science and Technology, Wuhan Sports University, Wuhan, ChinaYizhang JiangSchool of Artificial Intelligence and Computer Science, Jiangnan University, Wuxi, ChinaXin NingInstitute of Semiconductors, Chinese Academy of Sciences, Beijing, ChinaPengjiang QianSchool of Artificial Intelligence and Computer Science, Jiangnan University, Wuxi, China
2022en
ABI

Abstract

Cognitive computing is dedicated to researching a computing principle and method that can simulate the intelligence ability of human brain. Human emotion is the basic component of human cognitive activities. Electroencephalogram (EEG) computer signals obtained from a brain computer interface are difficult to conceal, and using machine learning methods to analyze EEG emotion is a hot topic in artificial intelligence. However, the EEG signal is non-stationary, making it difficult to select sufficient data from the same person to train a classifier for a subject. To promote the performance of emotion recognition methods, a multi-source domain transfer discriminative dictionary learning modeling (MDTDDL) is proposed in this study. The method integrates transfer learning and dictionary learning in a learning model, including the concepts of subspace learning, manifold smoothness, margin-based discriminant embedding, and large margin. The domain-specific transformation matrix projects EEG signals from various domains into the transfer subspace. The domain-invariant dictionary can find potential connections between multiple source domains and target domain. The manifold smoothness and margin-based discriminant embedding term further improve the model’s learning ability. The alternating optimization technique is used in model solving to efficiently compute model parameters. Experiments on the SEED and DEAP datasets demonstrate the effectiveness of MDTDDL.

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