Multi-source deep domain adaptation ensemble framework for cross-dataset motor imagery EEG transfer learning

• Published in: Physiological measurement Vol. 45; no. 5; pp. 55024 - 55044
• Main Authors: Miao, Minmin, Yang, Zhong, Sheng, Zhenzhen, Xu, Baoguo, Zhang, Wenbin, Cheng, Xinmin
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 01.05.2024
• Subjects: cross-dataset; deep domain adaptation; motor imagery EEG; multi-source; transfer learning; transfer learning; motor imagery EEG; deep domain adaptation; multi-source; cross-dataset
• ISSN: 0967-3334; 1361-6579; 1361-6579
• DOI: 10.1088/1361-6579/ad4e95

Objective . Electroencephalography (EEG) is an important kind of bioelectric signal for measuring physiological activities of the brain, and motor imagery (MI) EEG has significant clinical application prospects. Convolutional neural network has become a mainstream algorithm for MI EEG classification, however lack of subject-specific data considerably restricts its decoding accuracy and generalization performance. To address this challenge, a novel transfer learning (TL) framework using auxiliary dataset to improve the MI EEG classification performance of target subject is proposed in this paper. Approach . We developed a multi-source deep domain adaptation ensemble framework (MSDDAEF) for cross-dataset MI EEG decoding. The proposed MSDDAEF comprises three main components: model pre-training, deep domain adaptation, and multi-source ensemble. Moreover, for each component, different designs were examined to verify the robustness of MSDDAEF. Main results . Bidirectional validation experiments were performed on two large public MI EEG datasets (openBMI and GIST). The highest average classification accuracy of MSDDAEF reaches 74.28% when openBMI serves as target dataset and GIST serves as source dataset. While the highest average classification accuracy of MSDDAEF is 69.85% when GIST serves as target dataset and openBMI serves as source dataset. In addition, the classification performance of MSDDAEF surpasses several well-established studies and state-of-the-art algorithms. Significance . The results of this study show that cross-dataset TL is feasible for left/right-hand MI EEG decoding, and further indicate that MSDDAEF is a promising solution for addressing MI EEG cross-dataset variability.