Abstract

The steady-state motion visual evoked potential (SSMVEP) collected from the scalp suffers from strong noise and is contaminated by artifacts such as the electrooculogram (EOG) and the electromyogram (EMG). Spatial filtering methods can fuse the information of different brain regions, which is beneficial for the enhancement of the active components of the SSMVEP. Traditional spatial filtering methods fuse electroencephalogram (EEG) in the time domain. Based on the idea of image fusion, this study proposed an SSMVEP enhancement method based on time-frequency (T-F) image fusion. The purpose is to fuse SSMVEP in the T-F domain and improve the enhancement effect of the traditional spatial filtering method on SSMVEP active components. Firstly, two electrode signals were transformed from the time domain to the T-F domain via short-time Fourier transform (STFT). The transformed T-F signals can be regarded as T-F images. Then, two T-F images were decomposed via two-dimensional multiscale wavelet decomposition, and both the high-frequency coefficients and low-frequency coefficients of the wavelet were fused by specific fusion rules. The two images were fused into one image via two-dimensional wavelet reconstruction. The fused image was subjected to mean filtering, and finally, the fused time-domain signal was obtained by inverse STFT (ISTFT). The experimental results show that the proposed method has better enhancement effect on SSMVEP active components than the traditional spatial filtering methods. This study indicates that it is feasible to fuse SSMVEP in the T-F domain, which provides a new idea for SSMVEP analysis.

Highlights

  • To improve the comfort of light-flashing stimulation, we proposed a steady-state motion visual evoked potential (SSMVEP) method to replace light-flashing stimulation with motion stimulation in the previous study [1]

  • The SSMVEP signal was selected as a research object. e SSMVEP collected from the scalp will be contaminated by a variety of artifacts, such as the electrooculogram (EOG) and electromyogram (EMG)

  • Two electrode signals were transformed from the time domain to the T-F domain via short-time Fourier transform (STFT). en, two T-F images were decomposed by two-dimensional multiscale wavelet decomposition, and both the high-frequency coefficients and low-frequency coefficients of the wavelet were fused by specific fusion rules

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Summary

Introduction

To improve the comfort of light-flashing stimulation, we proposed a steady-state motion visual evoked potential (SSMVEP) method to replace light-flashing stimulation with motion stimulation in the previous study [1]. The SSMVEP signal was selected as a research object. E SSMVEP collected from the scalp will be contaminated by a variety of artifacts, such as the electrooculogram (EOG) and electromyogram (EMG). The requirements for subsequent signal processing are high. In electroencephalogram (EEG) signal processing, using multichannel EEG is beneficial and effective [2, 3]. In the EEG literature, the method for linearly fusing the multilead signals into single-channel or multichannel signals is called spatial filtering. Spatial filtering combines the EEG information of different brain regions, which enhances the active components of the EEG [4, 5]

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