Visual Stimuli for P300-Based Brain-Computer Interfaces: Color, Shape, and Mobility

The purpose of this study was to identify the impact of different discriminative features of stimuli in a P300 brain-computer interface paradigm on overall performance and evoked potentials. It has been shown that stimuli sets with a greater number of discriminative features yield better target sele...

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Veröffentlicht in:	Moscow University biological sciences bulletin 2018-04, Vol.73 (2), p.92-96
Hauptverfasser:	Grigoryan, R. K., Krysanova, E. U., Kirjanov, D. A., Kaplan, A. Ya
Format:	Artikel
Sprache:	eng
Schlagworte:	Biochemistry Biomedical and Life Sciences Brain Cell Biology Color Computer applications Environmental effects Event-related potentials Implants Interfaces Life Sciences Physiology Plant Sciences Semantics Visual stimuli Zoology
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creator	Grigoryan, R. K. Krysanova, E. U. Kirjanov, D. A. Kaplan, A. Ya
description	The purpose of this study was to identify the impact of different discriminative features of stimuli in a P300 brain-computer interface paradigm on overall performance and evoked potentials. It has been shown that stimuli sets with a greater number of discriminative features yield better target selection accuracy. Target selection accuracy was significantly higher for the stimuli that differ from each other by color, shape, and semantics. Highest performance was achieved with the stimuli set containing the largest number of discriminative features, namely a set of nine different-colored letters. This result is mainly due to higher mean P300 peak amplitude for stimuli sets that contain more discriminative features. The results of the study can be used for designing a better user experience in brain-computer interfacing (BCI). Motion of the stimuli presentation point and characteristics of this motion (linear or pseudorandom) did not have any impact on BCI performance. This result is promising for future BCI designs with rapid serial visual presentation using mobile robots or augmented reality as stimuli presentation environment.
doi_str_mv	10.3103/S0096392518020037
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The results of the study can be used for designing a better user experience in brain-computer interfacing (BCI). Motion of the stimuli presentation point and characteristics of this motion (linear or pseudorandom) did not have any impact on BCI performance. 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subjects	Biochemistry Biomedical and Life Sciences Brain Cell Biology Color Computer applications Environmental effects Event-related potentials Implants Interfaces Life Sciences Physiology Plant Sciences Semantics Visual stimuli Zoology
title	Visual Stimuli for P300-Based Brain-Computer Interfaces: Color, Shape, and Mobility
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