Abstract

Independent component analysis (ICA) as a promising spatial filtering method can separate motor-related independent components (MRICs) from the multichannel electroencephalogram (EEG) signals. However, the unpredictable burst interferences may significantly degrade the performance of ICA-based brain-computer interface (BCI) system. In this study, we proposed a new algorithm frame to address this issue by combining the single-trial-based ICA filter with zero-training classifier. We developed a two-round data selection method to identify automatically the badly corrupted EEG trials in the training set. The “high quality” training trials were utilized to optimize the ICA filter. In addition, we proposed an accuracy-matrix method to locate the artifact data segments within a single trial and investigated which types of artifacts can influence the performance of the ICA-based MIBCIs. Twenty-six EEG datasets of three-class motor imagery were used to validate the proposed methods, and the classification accuracies were compared with that obtained by frequently used common spatial pattern (CSP) spatial filtering algorithm. The experimental results demonstrated that the proposed optimizing strategy could effectively improve the stability, practicality and classification performance of ICA-based MIBCI. The study revealed that rational use of ICA method may be crucial in building a practical ICA-based MIBCI system.

Highlights

  • Noninvasive brain-computer interfaces (BCIs) measure brain activities, and translate them directly into controlling commands to operate external devices without resorting to the peripheral muscular nerve system [1,2,3]

  • We investigated the influences of different artifacts on Independent component analysis (ICA)-based motor imagery BCI (MIBCI)

  • Since the unpredictable non-physiological artifacts would induce performance degradation and instability of ICA algorithm, we proposed a fully automated method to detect the artifact trials without using any predefined templates of the typical artifacts

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Summary

Introduction

Noninvasive brain-computer interfaces (BCIs) measure brain activities, and translate them directly into controlling commands to operate external devices without resorting to the peripheral muscular nerve system [1,2,3]. A common input for BCI systems is the scalp-recorded electroencephalogram (EEG) signal reflecting the electric field generated by the spontaneous electrophysiological activities of neurons. Recorded EEGs are inevitably contaminated with non-brain activity artifacts [4, 5] such as electromyograms (EMGs), electrooculograms (EOGs), electrocardiograms (ECGs) and various environmental electromagnetic interferences. EEGs are characterized by low spatial resolution due to the PLOS ONE | DOI:10.1371/journal.pone.0162657. A Fully Automated Trial Rejection Method for Motor Imagery Based BCI are available from the figshare database.(DOI:. A Fully Automated Trial Rejection Method for Motor Imagery Based BCI are available from the figshare database.(DOI:10. 6084/m9.figshare.2061654)

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