Abstract
Common spatial pattern (CSP) method is widely used for spatial filtering and brain pattern extraction from electroencephalogram (EEG) signals in motor imagery (MI)-based brain-computer interfaces (BCIs). The participant-specific time window relative to the visual cue has a significant impact on the effectiveness of the CSP. However, the time window is usually selected experientially or manually. To solve this problem, we propose a novel feature selection approach for MI-based BCIs. Specifically, multiple time segments were obtained by decomposing each EEG sample of the MI task. Furthermore, the features were extracted by CSP from each time segment and were combined to form a new feature vector. Finally, the optimal temporal combination patterns for the new feature vector were selected based on four feature selection algorithms, i.e., mutual information, least absolute shrinkage and selection operator, principal component analysis and stepwise linear discriminant analysis (denoted as MUIN, LASSO, PCA, and SWLDA, respectively), and the classification algorithm was employed to evaluate the average classification accuracy. With three BCI competition datasets, the results of the four proposed algorithms were compared with traditional CSP algorithm in classification accuracy. Experimental results show that compared with traditional algorithm, the proposed methods significantly improve performance. Specifically, the LASSO achieved the highest accuracy (88.58%) among the proposed methods. Importantly, the average classification accuracies using the proposed approaches significantly improved 10.14% (MUIN), 11.40% (LASSO), 6.08% (PCA), and 10.25% (SWLDA) compared to that using CSP. These results indicate that the proposed approach is expected to be practical in MI-based BCIs.
Highlights
Brain Computer Interface (BCI) is a direct communication system between the brain and external devices, which does not rely on human peripheral nerves and muscles (Wolpaw et al, 2002; NicolasAlonso and Gomez-Gil, 2012)
Among the four feature selection-based methods, the results show that the LASSO yield best average classification accuracy (88.6%) across all the participants compared to MUIN, Principal Component Analysis-Based (PCA), and Stepwise Linear Discriminant Analysis-Based (SWLDA)
A novel feature selection-based method of optimal temporal combination patterns is proposed for motor imagery (MI)-BCI systems
Summary
Brain Computer Interface (BCI) is a direct communication system between the brain and external devices, which does not rely on human peripheral nerves and muscles (Wolpaw et al, 2002; NicolasAlonso and Gomez-Gil, 2012). The most extensively used brain signals for BCI input are event-related potential (ERP) (Zhang et al, 2014; Jin et al, 2015, 2017; Yin et al, 2015, 2016; Xu et al, 2018), steady-state visual evoked potential (SSVEP) (Pan et al, 2013; Wang et al, 2016; Xing et al, 2018; Zhang et al, 2018), and motor-imagery (MI) (Zhang et al, 2015, 2017; Ang and Guan, 2017; Qiu et al, 2017; Meng et al, 2018; Lugo et al, 2019). Some MI-BCI systems depend on the well-known neurophysiological phenomenon of event-related synchronization (ERS) or eventrelated desynchronization (ERD), which is either enhancement or suppression of the EEG (Meng et al, 2013). Other MI-BCI systems use slow cortical potentials such as movement-related cortical potentials (Hinterberger et al, 2004; Ren et al, 2014)
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