Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition

Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition

Brain–computer interface is a new form of interaction between humans and machines. This interaction helps the human brain control or operate external devices directly using electroencephalograph (EEG) signals. In this study, we first adopt a canonical correlation analysis method to find the stimulat...

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Main Authors: Fan Zhang, Hang Yu, Jie Jiang, Zhangye Wang, Xujia Qin
Format: Article
Language:English
Published: Elsevier 2020-03-01
Series:Visual Informatics
Online Access:http://www.sciencedirect.com/science/article/pii/S2468502X19300658
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spelling doaj-c06d449f472f4a78a769f580e143b0652020-11-25T02:06:32ZengElsevierVisual Informatics2468-502X2020-03-014117Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognitionFan Zhang0Hang Yu1Jie Jiang2Zhangye Wang3Xujia Qin4College of Computer Science, Zhejiang University of Technology, ChinaCollege of Computer Science, Zhejiang University of Technology, ChinaCollege of Computer Science, Zhejiang University of Technology, China; Corresponding authors.State Key Lab of CAD&CG, Zhejiang University, ChinaCollege of Computer Science, Zhejiang University of Technology, China; Corresponding authors.Brain–computer interface is a new form of interaction between humans and machines. This interaction helps the human brain control or operate external devices directly using electroencephalograph (EEG) signals. In this study, we first adopt a canonical correlation analysis method to find the stimulation frequency by calculating the correlation coefficient between the EEG data and multiple sets of harmonics with different frequencies. Then, we select the maximum correlation coefficient as the stimulus frequency and consequently identify steady-state visual evoked potentials. Afterward, we introduce power spectral density to adjust the stimulus frequency and a voting mechanism to reduce the false activation rate. Finally, we build a virtual household electrical appliance brain–computer control interface, which achieves over 72.84% accuracy for three classification problems. Keywords: Brain–computer interface, Steady-state visually evoked potential, Canonical correlation analysishttp://www.sciencedirect.com/science/article/pii/S2468502X19300658
collection DOAJ
language English
format Article
sources DOAJ
author Fan Zhang
Hang Yu
Jie Jiang
Zhangye Wang
Xujia Qin
spellingShingle Fan Zhang
Hang Yu
Jie Jiang
Zhangye Wang
Xujia Qin
Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
Visual Informatics
author_facet Fan Zhang
Hang Yu
Jie Jiang
Zhangye Wang
Xujia Qin
author_sort Fan Zhang
title Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
title_short Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
title_full Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
title_fullStr Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
title_full_unstemmed Brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
title_sort brain–computer control interface design for virtual household appliances based on steady-state visually evoked potential recognition
publisher Elsevier
series Visual Informatics
issn 2468-502X
publishDate 2020-03-01
description Brain–computer interface is a new form of interaction between humans and machines. This interaction helps the human brain control or operate external devices directly using electroencephalograph (EEG) signals. In this study, we first adopt a canonical correlation analysis method to find the stimulation frequency by calculating the correlation coefficient between the EEG data and multiple sets of harmonics with different frequencies. Then, we select the maximum correlation coefficient as the stimulus frequency and consequently identify steady-state visual evoked potentials. Afterward, we introduce power spectral density to adjust the stimulus frequency and a voting mechanism to reduce the false activation rate. Finally, we build a virtual household electrical appliance brain–computer control interface, which achieves over 72.84% accuracy for three classification problems. Keywords: Brain–computer interface, Steady-state visually evoked potential, Canonical correlation analysis
url http://www.sciencedirect.com/science/article/pii/S2468502X19300658
work_keys_str_mv AT fanzhang braincomputercontrolinterfacedesignforvirtualhouseholdappliancesbasedonsteadystatevisuallyevokedpotentialrecognition
AT hangyu braincomputercontrolinterfacedesignforvirtualhouseholdappliancesbasedonsteadystatevisuallyevokedpotentialrecognition
AT jiejiang braincomputercontrolinterfacedesignforvirtualhouseholdappliancesbasedonsteadystatevisuallyevokedpotentialrecognition
AT zhangyewang braincomputercontrolinterfacedesignforvirtualhouseholdappliancesbasedonsteadystatevisuallyevokedpotentialrecognition
AT xujiaqin braincomputercontrolinterfacedesignforvirtualhouseholdappliancesbasedonsteadystatevisuallyevokedpotentialrecognition
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