Online Privacy-Preserving EEG Classification by Source-Free Transfer Learning

Electroencephalogram (EEG) signals play an important role in brain-computer interface (BCI) applications. Recent studies have utilized transfer learning to assist the learning task in the new subject, i.e., target domain, by leveraging beneficial information from previous subjects, i.e., source doma...

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Bibliographic Details
Published in:IEEE transactions on neural systems and rehabilitation engineering 2024-01, Vol.32, p.3059-3070
Main Authors: Wu, Hanrui, Ma, Zhengyan, Guo, Zhenpeng, Wu, Yanxin, Zhang, Jia, Zhou, Guoxu, Long, Jinyi
Format: Article
Language:English
Subjects:
Adaptation models
Brain modeling
Brain-computer interfaces
Electroencephalography
Feature extraction
multiple source domains
online transfer learning
Predictive models
Privacy
privacy preservation
Transfer learning
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Summary:Electroencephalogram (EEG) signals play an important role in brain-computer interface (BCI) applications. Recent studies have utilized transfer learning to assist the learning task in the new subject, i.e., target domain, by leveraging beneficial information from previous subjects, i.e., source domains. Nevertheless, EEG signals involve sensitive personal mental and health information. Thus, privacy concern becomes a critical issue. In addition, existing methods mostly assume that a portion of the new subject's data is available and perform alignment or adaptation between the source and target domains. However, in some practical scenarios, new subjects prefer prompt BCI utilization over the time-consuming process of collecting data for calibration and adaptation, which makes the above assumption difficult to hold. To address the above challenges, we propose Online Source-Free Transfer Learning (OSFTL) for privacy-preserving EEG classification. Specifically, the learning procedure contains offline and online stages. At the offline stage, multiple model parameters are obtained based on the EEG samples from multiple source subjects. OSFTL only needs access to these source model parameters to preserve the privacy of the source subjects. At the online stage, a target classifier is trained based on the online sequence of EEG instances. Subsequently, OSFTL learns a weighted combination of the source and target classifiers to obtain the final prediction for each target instance. Moreover, to ensure good transferability, OSFTL dynamically updates the transferred weight of each source domain based on the similarity between each source classifier and the target classifier. Comprehensive experiments on both simulated and real-world applications demonstrate the effectiveness of the proposed method, indicating the potential of OSFTL to facilitate the deployment of BCI applications outside of controlled laboratory settings.
ISSN:1534-4320
1558-0210
1558-0210
DOI:10.1109/TNSRE.2024.3445115