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A Wearable Brain-Computer Interface With Fewer EEG Channels for Online Motor Imagery Detection

Zuguang Rao, Junbiao Zhu, Zilin Lu, Rui Zhang, Kendi Li, Zijing Guan, Yuanqing Li

2024IEEE Transactions on Neural Systems and Rehabilitation Engineering11 citationsDOIOpen Access PDF

Abstract

Motor imagery-based brain-computer interfaces (MI-BCIs) have significant potential for neurorehabilitation and motor recovery. However, most BCI systems employ multi-channel electroencephalogram (EEG) recording devices, during which the pre-experimental preparation and post-experimental hair cleaning are time-consuming and inconvenient for stroke patients, and potentially affect their motivation for rehabilitation training. In this paper, we introduced a wearable MI-BCI system for online MI classification using a wireless headband device with four EEG channels to reduce setup time while enhancing portability. To validate the performance of the system in decoding MI-EEG signals, extensive experiments and comparisons were performed on sixty-six healthy subjects. Specifically, an offline and an online experiment with forty-six subjects were conducted, with the system achieving average offline and online accuracies of 85.21% and 76.54%, respectively. Furthermore, a comparison experiment involving another twenty subjects showed that the online performance of our headband device (77.84%) was comparable to that of a mature commercial Neuroscan device (76.50%). Compared to several existing portable systems, our wearable system achieved superior performance with fewer channels and was validated on a larger number of subjects. These results demonstrated that our wearable BCI system can reduce preparation time, enhance portability, and meet the classification performance requirements for BCI-based rehabilitation intervention, indicating its substantial potential for large-scale clinical applications in enhancing motor recovery of stroke patients.

Topics & Concepts

Brain–computer interfaceMotor imageryElectroencephalographyWearable computerInterface (matter)Computer scienceHuman–computer interactionPsychologyNeuroscienceEmbedded systemParallel computingMaximum bubble pressure methodBubbleEEG and Brain-Computer InterfacesNeuroscience and Neural EngineeringAdvanced Memory and Neural Computing