Abstract
Accurate and automatic classification of the speech imagery electroencephalography (EEG) signals from a Brain-Computer Interface (BCI) system is highly demanded in clinical diagnosis. The key factor in designing an automatic classification system is to extract essential features from the original input; though many methods have achieved great success in this domain, they may fail to process the multi-scale representations from different receptive fields and thus hinder the model from achieving a higher performance. To address this challenge, in this paper, we propose a novel dynamic multi-scale network to achieve the EEG signal classification. The whole classification network is based on ResNet, and the input signal first encodes the features by the Short-time Fourier Transform (STFT); then, to further improve the multi-scale feature extraction ability, we incorporate a dynamic multi-scale (DMS) layer, which allows the network to learn multi-scale features from different receptive fields at a more granular level. To validate the effectiveness of our designed network, we conduct extensive experiments on public dataset III of BCI competition II, and the experimental results demonstrate that our proposed dynamic multi-scale network could achieve promising classification performance in this task.
Highlights
The brain sends brainwaves (Shahid et al, 2010) that enable human beings to think and act
The EEG-based Brain-Computer Interface (BCI) system is divided into BCI based on steady-state visual evoked potential (SSVEP) and that based on sensorimotor rhythm (SMR) according to the type of EEG signals, and the latter is related to motor imagery (MI) (Schlögl et al, 2005; Zich et al, 2015)
The best performance of our method can achieve the accuracy of 90.47% since we adopt Short-time Fourier Transform (STFT) for preprocessing and incorporate the dynamic multi-scale (DMS) layer to our network
Summary
The brain sends brainwaves (Shahid et al, 2010) that enable human beings to think and act. During this process, people’s motion intention can be captured by collecting EEG signals [called motor imagery (MI) EEG] from the cerebral cortex (Schlögl et al, 2005). The EEG-based BCI system is divided into BCI based on steady-state visual evoked potential (SSVEP) and that based on sensorimotor rhythm (SMR) according to the type of EEG signals, and the latter is related to MI (Schlögl et al, 2005; Zich et al, 2015). When subjects are imagining movement to the left, the amplitude of mu and beta rhythm decreases
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