Motor-Imagery-Based Brain-Computer Interface Using Signal Derivation and Aggregation Functions

Fumanal-Idocin, J; Wang, Y-K; Lin, C-T; Fernandez, J; Sanz, JA; Bustince, H

Motor-Imagery-Based Brain-Computer Interface Using Signal Derivation and Aggregation Functions

Fumanal-Idocin, J Wang, Y-K Lin, C-T Fernandez, J Sanz, JA Bustince, H

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Publisher:: IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
Publication Type:: Journal Article
Citation:: IEEE Transactions on Cybernetics, 2022, 52, (8), pp. 7944-7955
Issue Date:: 2022-01-01

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Field	Value	Language
dc.contributor.author	Fumanal-Idocin, J
dc.contributor.author	Wang, Y-K
dc.contributor.author	Lin, C-T
dc.contributor.author	Fernandez, J
dc.contributor.author	Sanz, JA
dc.contributor.author	Bustince, H
dc.date.accessioned	2023-03-23T04:34:39Z
dc.date.available	2023-03-23T04:34:39Z
dc.date.issued	2022-01-01
dc.identifier.citation	IEEE Transactions on Cybernetics, 2022, 52, (8), pp. 7944-7955
dc.identifier.issn	2168-2267
dc.identifier.issn	2168-2275
dc.identifier.uri	http://hdl.handle.net/10453/168202
dc.description.abstract	Brain-computer interface (BCI) technologies are popular methods of communication between the human brain and external devices. One of the most popular approaches to BCI is motor imagery (MI). In BCI applications, the electroencephalography (EEG) is a very popular measurement for brain dynamics because of its noninvasive nature. Although there is a high interest in the BCI topic, the performance of existing systems is still far from ideal, due to the difficulty of performing pattern recognition tasks in EEG signals. This difficulty lies in the selection of the correct EEG channels, the signal-to-noise ratio of these signals, and how to discern the redundant information among them. BCI systems are composed of a wide range of components that perform signal preprocessing, feature extraction, and decision making. In this article, we define a new BCI framework, called enhanced fusion framework, where we propose three different ideas to improve the existing MI-based BCI frameworks. First, we include an additional preprocessing step of the signal: a differentiation of the EEG signal that makes it time invariant. Second, we add an additional frequency band as a feature for the system: the sensorimotor rhythm band, and we show its effect on the performance of the system. Finally, we make a profound study of how to make the final decision in the system. We propose the usage of both up to six types of different classifiers and a wide range of aggregation functions (including classical aggregations, Choquet and Sugeno integrals, and their extensions and overlap functions) to fuse the information given by the considered classifiers. We have tested this new system on a dataset of 20 volunteers performing MI-based brain-computer interface experiments. On this dataset, the new system achieved 88.80% accuracy. We also propose an optimized version of our system that is able to obtain up to 90.76%. Furthermore, we find that the pair Choquet/Sugeno integrals and overlap functions are the ones providing the best results.
dc.format	Print-Electronic
dc.language	eng
dc.publisher	IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
dc.relation.ispartof	IEEE Transactions on Cybernetics
dc.relation.isbasedon	10.1109/tcyb.2021.3073210
dc.rights	info:eu-repo/semantics/closedAccess
dc.subject	0102 Applied Mathematics, 0801 Artificial Intelligence and Image Processing, 0906 Electrical and Electronic Engineering
dc.subject.classification	Artificial Intelligence & Image Processing
dc.subject.mesh	Algorithms
dc.subject.mesh	Brain
dc.subject.mesh	Brain-Computer Interfaces
dc.subject.mesh	Electroencephalography
dc.subject.mesh	Humans
dc.subject.mesh	Imagination
dc.subject.mesh	Signal Processing, Computer-Assisted
dc.subject.mesh	Brain
dc.subject.mesh	Humans
dc.subject.mesh	Electroencephalography
dc.subject.mesh	Imagination
dc.subject.mesh	Algorithms
dc.subject.mesh	Signal Processing, Computer-Assisted
dc.subject.mesh	Brain-Computer Interfaces
dc.subject.mesh	Algorithms
dc.subject.mesh	Brain
dc.subject.mesh	Brain-Computer Interfaces
dc.subject.mesh	Electroencephalography
dc.subject.mesh	Humans
dc.subject.mesh	Imagination
dc.subject.mesh	Signal Processing, Computer-Assisted
dc.title	Motor-Imagery-Based Brain-Computer Interface Using Signal Derivation and Aggregation Functions
dc.type	Journal Article
utslib.citation.volume	52
utslib.location.activity	United States
utslib.for	0102 Applied Mathematics
utslib.for	0801 Artificial Intelligence and Image Processing
utslib.for	0906 Electrical and Electronic Engineering
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology
pubs.organisational-group	/University of Technology Sydney/Strength - AAII - Australian Artificial Intelligence Institute
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology/School of Computer Science
utslib.copyright.status	closed_access	*
pubs.consider-herdc	false
dc.date.updated	2023-03-23T04:34:38Z
pubs.issue	8
pubs.publication-status	Published online
pubs.volume	52
utslib.citation.issue	8

Abstract:

Brain-computer interface (BCI) technologies are popular methods of communication between the human brain and external devices. One of the most popular approaches to BCI is motor imagery (MI). In BCI applications, the electroencephalography (EEG) is a very popular measurement for brain dynamics because of its noninvasive nature. Although there is a high interest in the BCI topic, the performance of existing systems is still far from ideal, due to the difficulty of performing pattern recognition tasks in EEG signals. This difficulty lies in the selection of the correct EEG channels, the signal-to-noise ratio of these signals, and how to discern the redundant information among them. BCI systems are composed of a wide range of components that perform signal preprocessing, feature extraction, and decision making. In this article, we define a new BCI framework, called enhanced fusion framework, where we propose three different ideas to improve the existing MI-based BCI frameworks. First, we include an additional preprocessing step of the signal: a differentiation of the EEG signal that makes it time invariant. Second, we add an additional frequency band as a feature for the system: the sensorimotor rhythm band, and we show its effect on the performance of the system. Finally, we make a profound study of how to make the final decision in the system. We propose the usage of both up to six types of different classifiers and a wide range of aggregation functions (including classical aggregations, Choquet and Sugeno integrals, and their extensions and overlap functions) to fuse the information given by the considered classifiers. We have tested this new system on a dataset of 20 volunteers performing MI-based brain-computer interface experiments. On this dataset, the new system achieved 88.80% accuracy. We also propose an optimized version of our system that is able to obtain up to 90.76%. Furthermore, we find that the pair Choquet/Sugeno integrals and overlap functions are the ones providing the best results.

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http://hdl.handle.net/10453/168202