Comparative analysis of two-group supervised classification algorithms in the study of P300-based brain-computer interface

Małgorzata Plechawska-Wójcik,Bernadetta Michalik,Monika Kaczorowska,M Kulisz,M Szala,Z Czyż,T Tulwin,M Badurowicz,J Kujawska,M Chmielewska,K Falkowicz,W Cel

doi:10.1051/matecconf/201925203010

Małgorzata Plechawska-Wójcik, Bernadetta Michalik + Show 10 more

Open Access

https://doi.org/10.1051/matecconf/201925203010

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Journal: MATEC Web of Conferences	Publication Date: Jan 1, 2019
Citations: 1	License type: CC BY 4.0

Abstract

The main goal of the paper is to perform a comparative accuracy analysis of the two-group classification of EEG data collected during the P300-based brain-computer interface tests. The brain-computer interface is a technology that allows establishing communication between a human brain and external devices. BCIs may be applied in medicine to improve the life of disabled people and as well for entertainment. The P300 is an event-related potential (ERP) appearing about 300 ms after the occurrence of the stimulus of visual, auditory or sensory nature. It is based on the phenomenon observed in anticipation for a target event among non-target events. The 21-channel 201 Mitsar amplifier was used during the experiment to store EEG data from seven electrodes placed on the dedicated cap. The study was conducted on a group of five persons using P300 scenario available in OpenVibe software. The experiment was based on three steps the classifier learning process, comparison and averaging of the obtained result and the final test of the classifier. The comparative analysis was performed with the application of two supervised classification methods: Linear Discriminant Analysis (LDA) and Multi-layer Perceptron (MLP). The preliminary data analysis, extraction and feature selection was performed prior to the classification.

Highlights

Neuroimaging is associated with a group of research methods used to study the structure and function of the brain
By acquiring and translating brain signals to specific commands, the Brain-Computer Interface (BCI) system can be used as an alternative method of communication for people with severe neuromuscular disorders
The paper presents the research of BCI based on P300 paradigm

Summary

Introduction

Neuroimaging is associated with a group of research methods used to study the structure and function of the brain. Due to its remarkable time resolution, EEG is applied to study changes in brain activity over time and to analyse responses to external stimuli. On the basis of the signal that changes over time, one can locate and remove distortions, i.e. muscle artefacts. The EEG signal represents curves illustrating voltage changes in time occurring between the electrodes. The Brain-Computer Interface (BCI) is a system for communication with a computer using brain signals. By acquiring and translating brain signals to specific commands, the BCI system can be used as an alternative method of communication for people with severe neuromuscular disorders. Brain signals can be obtained by invasive or non-invasive methods

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