Abstract

Brain-computer interface (BCI) has emerged as a popular research domain in recent years. The use of electroencephalography (EEG) signals for motor imagery (MI) based BCI has gained widespread attention. The first step in its implementation is to fetch EEG signals from scalp of human subject. The preprocessing of EEG signals is done before applying feature extraction, selection and classification techniques as main steps of signal processing. In preprocessing stage, artifacts are removed from raw brain signals before these are input to next stage of feature extraction. Subsequently classifier algorithms are used to classify selected features into intended MI tasks. The major challenge in a BCI systems is to improve classification accuracy of a BCI system. In this paper, an approach based on Support Vector Machine (SVM), is proposed for signal classification to improve accuracy of the BCI system. The parameters of kernel are varied to attain improvement in classification accuracy. Independent component analysis (ICA) technique is used for preprocessing and filter bank common spatial pattern (FBCSP) for feature extraction and selection. The proposed approach is evaluated on data set 2a of BCI Competition IV by using 5-fold crossvalidation procedure. Results show that it performs better in terms of classification accuracy, as compared to other methods reported in literature.

Highlights

  • The brain-computer interface (BCI) is a method of establishing a communication channel between a user and system, which is independent of brain's normal output nerve pathways and muscles [1]

  • This paper proposes a filter bank common spatial pattern (FBCSP)/Support Vector Machine (SVM) machine learning approach for multi-class motor imagery (MI) based BCI systems

  • The SVM is used for classification of multiclass MI EEG signals

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Summary

Introduction

The brain-computer interface (BCI) is a method of establishing a communication channel between a user and system, which is independent of brain's normal output nerve pathways and muscles [1]. It provides an advanced technology which can translate intent of a user from brain signals directly into commands and can establish a direct communication channel between human brain and external devices [2]. In EEG based BCI systems, noninvasive sensors are placed on the scalp of user to sense electrical activity of the brain [5]. The standardized international 10-20 electrode placement system of EEG demarcates the position of electrodes on various parts of the subject’s scalp [7]

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