Abstract
The motor-imagery brain-computer interface system (MI-BCI) has a board prospect for development. However, long calibration time and lack of enough MI commands limit its use in practice. In order to enlarge the command set, we add the combinations of traditional MI commands as new commands into the command set. We also design an algorithm based on transfer learning so as to decrease the calibration time for collecting EEG signal and training model. We create feature extractor based on data from traditional commands and transfer patterns through the data from new commands. Through the comparison of the average accuracy between our algorithm and traditional algorithms and the visualization of spatial patterns in our algorithm, we find that the accuracy of our algorithm is much higher than traditional algorithms, especially as for the low-quality datasets. Besides, the visualization of spatial patterns is meaningful. The algorithm based on transfer learning takes the advantage of the information from source data. We enlarge the command set while shortening the calibration time, which is of significant importance to the MI-BCI application.
Highlights
As a technique decoding brain activity, Brain-Computer Interface (BCI) based on electroencephalogram (EEG) enables people to interact with computers without the involvement of peripheral muscular activity, which builds a communication bridge between the brain and computer
As for the third group which is the classification between old command and new command, we make the classification for each two groups which means left hand (LH) vs. left hand and both feet simultaneously (LH&F), LH vs. right hand (RH)&F, LH vs. left hand and right hand simultaneously (LH&RH), RH vs. LH&F, RH vs. right hand and both feet simultaneously (RH&F), RH vs. LH&RH, F vs. LH&F, F vs. RH&F, and F vs. LH&RH
Comparing the accuracy of all tasks using the same source data, we find that our spatial filters can classify both old commands and both new commands in a similar accuracy
Summary
As a technique decoding brain activity, Brain-Computer Interface (BCI) based on electroencephalogram (EEG) enables people to interact with computers without the involvement of peripheral muscular activity, which builds a communication bridge between the brain and computer. Pattern classification, machine learning, and other techniques, the BCI system translates different kinds of brain activities such as attentive mental states [1], motor imagery [2,3,4,5] (MI), and so on into machine instruction for controlling devices. Motor imagery is a BCI paradigm in which brain activity is generated at the sensorimotor cortex during the imagination of the limb movement [9] such as left hand (LH), right hand (RH), and both feet (F). The power suppression and Computational and Mathematical Methods in Medicine enhancement observed through EEG signal are, respectively, called event-related desynchronization (ERD) and eventrelated synchronization (ERS) [12]. The ERD/ERS patterns can be used for translating brain activity and classifying the imagination of limbs through machine learning
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