Abstract
Motor imagery (MI) brain–computer interfaces (BCIs) have been used for a wide variety of applications due to their intuitive matching between the user’s intentions and the performance of tasks. Applying dry electroencephalography (EEG) electrodes to MI BCI applications can resolve many constraints and achieve practicality. In this study, we propose a multi-domain convolutional neural networks (MD-CNN) model that learns subject-specific and electrode-dependent EEG features using a multi-domain structure to improve the classification accuracy of dry electrode MI BCIs. The proposed MD-CNN model is composed of learning layers for three domain representations (time, spatial, and phase). We first evaluated the proposed MD-CNN model using a public dataset to confirm 78.96% classification accuracy for multi-class classification (chance level accuracy: 30%). After that, 10 healthy subjects participated and performed three classes of MI tasks related to lower-limb movement (gait, sitting down, and resting) over two sessions (dry and wet electrodes). Consequently, the proposed MD-CNN model achieved the highest classification accuracy (dry: 58.44%; wet: 58.66%; chance level accuracy: 43.33%) with a three-class classifier and the lowest difference in accuracy between the two electrode types (0.22%, d = 0.0292) compared with the conventional classifiers (FBCSP, EEGNet, ShallowConvNet, and DeepConvNet) that used only a single domain. We expect that the proposed MD-CNN model could be applied for developing robust MI BCI systems with dry electrodes.
Highlights
A brain–computer interface (BCI) is a system that decodes the user’s intent from brain signals and allows the user to control a computer or other external device without actual movement [1,2,3]
Wet electrode BCI has been widely used for a variety of research purposes but has practical limitations involving discomfort with the wet gel, time constraints, and wearing time [20,21,22,23], but it achieves low impedance and high signal-tonoise ratio (SNR) signals due to the conductive gel placed between the electrode and the skin [21,24]
We investigated the motor imagery (MI) BCI classification performance with dry and wet electrodes by using convolutional neural network (CNN)-based algorithms
Summary
A brain–computer interface (BCI) is a system that decodes the user’s intent from brain signals and allows the user to control a computer or other external device without actual movement [1,2,3]. Dry electrode BCI, which measures EEG signals through spike electrodes that directly touch the scalp without the use of wet gels, has practical aspects that solve the constraints of wet gels but produces low SNR and high impedance signals [25,26,27]. Despite these limitations, the practicality of using dry electrode BCI is an attractive advantage that cannot be abandoned
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