Abstract
Electroencephalogram (EEG) signal classification plays an important role to facilitate physically impaired patients by providing brain-computer interface (BCI)-controlled devices. However, practical applications of BCI make it difficult to decode motor imagery-based brain signals for multiclass classification due to their non-stationary nature. In this study, we aim to improve multiclass classification accuracy for motor imagery movement using sub-band common spatial patterns with sequential feature selection (SBCSP-SBFS) method. Filter bank having bandpass filters of different overlapped frequency cutoffs is applied to suppress the noise signals from raw EEG signals. The output of these sub-band filters is sent for feature extraction by applying common spatial pattern (CSP) and linear discriminant analysis (LDA). As all of the extracted features are not necessary for classification therefore, selection of optimal features is done by passing the extracted features to sequential backward floating selection (SBFS) technique. Three different classifiers were then trained on these optimal features, i.e., support vector machine (SVM), Naïve-Bayesian Parzen-Window (NBPW), and k-Nearest Neighbor (KNN). Results are evaluated on two datasets, i.e., Emotiv Epoc and wet gel electrodes for three classes, i.e., right-hand motor imagery, left hand motor imagery, and rest state. The proposed model yields a maximum accuracy of 60.61% in case of Emotiv Epoc headset and 86.50% for wet gel electrodes. The computed accuracy shows an increase of 7% as compared to previously implemented multiclass EEG classification.
Highlights
Brain signals, produced as a result of interneuronal brain activity, can be measured using neuroimaging technique known as an electroencephalogram (EEG) [1]
Acquisition of EEG signals by using non-invasive techniques has an influence of external noise; the acquired signal is contaminated with artifacts such as signals produced as a result of muscle movement, cable noise, and environment noise [6]
This paper aims to implement multiclass classification to improve the results of motor imagery brain signals by using sub-band common spatial patterns with sequential backward floating selection (SBCSP-SBFS)
Summary
Brain signals, produced as a result of interneuronal brain activity, can be measured using neuroimaging technique known as an electroencephalogram (EEG) [1]. EEG signal has a low spatial resolution, low signal-to-noise ratio (SNR) and its measurement mainly attribute to the volume conduction, which signifies the electrical field of the brain that is conducted from the source to the scalp [8]. To measure this low SNR and spatial resolution, common spatial pattern (CSP) was proposed to efficiently extract spatial features for motor imagery brain signals. To overcome this problem, EEG signal is divided into different sub-bands to extract information from different portions of the signal and the selection of features from extracted features on the basis of different information produces better results [10,11,12,13,14]
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