Abstract
Achieving high classification performance is challenging due to non-stationarity and low signal-to-noise ratio (low SNR) characteristics of EEG signals. Spatial filtering is commonly used to improve the SNR yet the individual differences in the underlying temporal or frequency information is often ignored. This paper investigates motor imagery signals via orthogonal wavelet decomposition, by which the raw signals are decomposed into multiple unrelated sub-band components. Furthermore, channel-wise spectral filtering via weighting the sub-band components are implemented jointly with spatial filtering to improve the discriminability of EEG signals, with an l2-norm regularization term embedded in the objective function to address the underlying over-fitting issue. Finally, sparse Bayesian learning with Gaussian prior is applied to the extracted power features, yielding an RVM classifier. The classification performance of SEOWADE is significantly better than those of several competing algorithms (CSP, FBCSP, CSSP, CSSSP, and shallow ConvNet). Moreover, scalp weight maps of the spatial filters optimized by SEOWADE are more neurophysiologically meaningful. In summary, these results demonstrate the effectiveness of SEOWADE in extracting relevant spatio-temporal information for single-trial EEG classification.
Highlights
Brain-computer interface (BCI) systems provide an approach for communicating with the external world by brain signals (Lemm et al, 2011)
The binary classification performance of SEOWADE algorithm applied to three real EEG data sets is shown
An SEOWADE algorithm based on orthogonal wavelet decomposition is proposed for motor imagery EEG signal classification
Summary
Brain-computer interface (BCI) systems provide an approach for communicating with the external world by brain signals (Lemm et al, 2011). BCI systems based on Electroencephalogram (EEG) is the most common non-invasive modality, as EEG is inexpensive and has high temporal resolution. Motor imagery based BCI is a commonly applied paradigm that can efficiently decode the imagination of movement, and related features are derived from event-related desynchronization/synchronization (ERD/ERS) (Blankertz et al, 2008). The signal processing steps of a BCI system include brain signal acquisition, EEG signal preprocessing, feature extraction and feature classification. The feature extraction stage forms discriminative features for the performed tasks in the spatial domain, temporal domain or frequency domain. The extracted features are used to train a classification or regression model
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
