Abstract
In this paper, we propose a set of wavelet-based combined feature vectors and a Gaussian mixture model (GMM)-supervector to enhance training speed and classification accuracy in motor imagery brain–computer interfaces. The proposed method is configured as follows: first, wavelet transforms are applied to extract the feature vectors for identification of motor imagery electroencephalography (EEG) and principal component analyses are used to reduce the dimensionality of the feature vectors and linearly combine them. Subsequently, the GMM universal background model is trained by the expectation–maximization (EM) algorithm to purify the training data and reduce its size. Finally, a purified and reduced GMM-supervector is used to train the support vector machine classifier. The performance of the proposed method was evaluated for three different motor imagery datasets in terms of accuracy, kappa, mutual information, and computation time, and compared with the state-of-the-art algorithms. The results from the study indicate that the proposed method achieves high accuracy with a small amount of training data compared with the state-of-the-art algorithms in motor imagery EEG classification.
Highlights
A brain–computer interface (BCI) refers to the technology that analyzes human’s mental activity to enable the brain to issue orders directly to computers [1,2]
We propose a method to improve the speed and classification accuracy of motor imagery BCI using a wavelet-based combined feature vector and a Gaussian mixture model (GMM)-supervector
By comparing the discrete wavelet transform (DWT), continuous wavelet transform (CWT), and combined feature vectors for the three datasets in terms of accuracy, we proved the efficiency of combined feature vectors
Summary
A brain–computer interface (BCI) refers to the technology that analyzes human’s mental activity to enable the brain to issue orders directly to computers [1,2]. BCIs use brain waves as input signals. Brain waves are very sensitive to the size of the user’s head, the state of the user, the position of the electrodes, psychological conditions, the ambient environment, etc. Electroencephalography (EEG) exhibit large deviations among users. This makes BCIs trained based on a particular person difficult to use on other subjects. BCIs require retraining whenever there are changes in the user, or in the environment or state of the user. Retraining is quite time-consuming, and may require longer periods of time to carry out, depending upon the situation [5]
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