Abstract
Motor imagery (MI) is a typical BCI paradigm and has been widely applied into many aspects (e.g. brain-driven wheelchair and motor function rehabilitation training). Although significant achievements have been achieved, multiple motor imagery decoding is still unsatisfactory. To deal with this challenging issue, firstly, a segment of electroencephalogram was extracted and preprocessed. Secondly, we applied a filter bank common spatial pattern (FBCSP) with one-vs-rest (OVR) strategy to extract the spatio-temporal-frequency features of multiple MI. Thirdly, the F-score was employed to optimise and select these features. Finally, the optimized features were fed to the spiking neural networks (SNN) for classification. Evaluation was conducted on two public multiple MI datasets (Dataset IIIa of the BCI competition III and Dataset IIa of the BCI competition IV). Experimental results showed that the average accuracy of the proposed framework reached up to 90.09% (kappa: 0.868) and 81.33% (kappa: 0.751) on the two public datasets, respectively. The achieved performance (accuracy and kappa) was comparable to the best one of the compared methods. This study demonstrated that the proposed method can be used as an alternative approach for multiple MI decoding and it provided a potential solution for online multiple MI detection.
Highlights
Electroencephalography (EEG) signal is usually used in brain-computer interface (BCI) systems due to its high temporal resolution [1]
EXPERIMENTAL RESULTS To assess the impact of the frequency bands on Motor imagery (MI)-BCI performance, we evaluated the Common spatial pattern (CSP) and filter bank common spatial pattern (FBCSP) methods for the following cases: 1) CSP: For the time window optimization problem of two datasets, it has been studied in [20], [39], [40]
2) 2FBCSP: The same time windows were used. 16 eigenvalues were extracted from the frequency bands 7-14 Hz and 14-30 Hz
Summary
Electroencephalography (EEG) signal is usually used in brain-computer interface (BCI) systems due to its high temporal resolution [1]. Motor imagery (MI)-based BCI is one of classical paradigms and has been employed to restore the communication pathway or movement function for disabled, paralyzed, and stroke patients [2], [3]. In the establishment of a BCI system, feature extraction is a crucial step. Common spatial pattern (CSP) is a widely used method to extract spacial features as it effectively constructs the best spatial filter for differentiating two classes of motor imagery. As CSP searches the best spatial filter by considering temporal dynamics, it depends on the information in the temporal domain and is sensitive to temporal noise.
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