Abstract
With the rapid development of deep learning, more and more deep learning-based motor imagery electroencephalograph (EEG) decoding methods have emerged in recent years. However, the existing deep learning-based methods usually only adopt the constraint of classification loss, which hardly obtains the features with high discrimination and limits the improvement of EEG decoding accuracy. In this paper, a discriminative feature learning strategy is proposed to improve the discrimination of features, which includes the central distance loss (CD-loss), the central vector shift strategy, and the central vector update process. First, the CD-loss is proposed to make the same class of samples converge to the corresponding central vector. Then, the central vector shift strategy extends the distance between different classes of samples in the feature space. Finally, the central vector update process is adopted to avoid the non-convergence of CD-loss and weaken the influence of the initial value of central vectors on the final results. In addition, overfitting is another severe challenge for deep learning-based EEG decoding methods. To deal with this problem, a data augmentation method based on circular translation strategy is proposed to expand the experimental datasets without introducing any extra noise or losing any information of the original data. To validate the effectiveness of the proposed method, we conduct some experiments on two public motor imagery EEG datasets (BCI competition IV 2a and 2b dataset), respectively. The comparison with current state-of-the-art methods indicates that our method achieves the highest average accuracy and good stability on the two experimental datasets.
Highlights
T HE brain-computer interfaces (BCIs) provide a new communication approach between the human brain and exter-Manuscript received October 3, 2020; revised November 25, 2020 and December 27, 2020; accepted January 12, 2021
Unlike other motor imagery EEG decoding methods based on deep learning, we creatively propose the central distance loss (CD-loss), the central vector shift strategy, and the central vector update process, which are helpful to obtain more discriminative features and achieve better classification performance
To evaluate the effectiveness of the CD-loss, the central vector shift strategy, and the central vector update process of the proposed discriminative feature learning strategy, we carry out several comparative experiments on the BCI competition IV 2a dataset
Summary
T HE brain-computer interfaces (BCIs) provide a new communication approach between the human brain and exter-Manuscript received October 3, 2020; revised November 25, 2020 and December 27, 2020; accepted January 12, 2021. This technology can be applied in various occasions, such as helping people who suffer from stroke, spinal cord injury, and amyotrophic lateral sclerosis, control external devices and improve their quality of life [2], [3]. Through the motor imagery based EEG decoding, disabled people can control assistive robots [7] or wheelchairs [8] to complete daily activities, such as moving and drinking, which has proved to be helpful for stroke rehabilitation [9]–[11]
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