A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface

A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface

Imagery-based brain-computer interfaces (BCIs) aim to decode different neural activities into control signals by identifying and classifying various natural commands from electroencephalogram (EEG) patterns and then control corresponding equipment. However, several traditional BCI recognition algori...

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Bibliographic Details
Main Authors: Xiaofei Zhang, Tao Wang, Qi Xiong, Yina Guo
Format: Article
Language:English
Published: Hindawi Limited 2021-01-01
Series:Computational Intelligence and Neuroscience
Online Access:http://dx.doi.org/10.1155/2021/6614677
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spelling doaj-0cad3ee31e1f49078a720150a44291282021-04-05T00:01:04ZengHindawi LimitedComputational Intelligence and Neuroscience1687-52732021-01-01202110.1155/2021/6614677A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer InterfaceXiaofei Zhang0Tao Wang1Qi Xiong2Yina Guo3School of Electronic Information EngineeringState Grid Yangquan Power Supply CompanySchool of Electronic Information EngineeringSchool of Electronic Information EngineeringImagery-based brain-computer interfaces (BCIs) aim to decode different neural activities into control signals by identifying and classifying various natural commands from electroencephalogram (EEG) patterns and then control corresponding equipment. However, several traditional BCI recognition algorithms have the “one person, one model” issue, where the convergence of the recognition model’s training process is complicated. In this study, a new BCI model with a Dense long short-term memory (Dense-LSTM) algorithm is proposed, which combines the event-related desynchronization (ERD) and the event-related synchronization (ERS) of the imagery-based BCI; model training and testing were conducted with its own data set. Furthermore, a new experimental platform was built to decode the neural activity of different subjects in a static state. Experimental evaluation of the proposed recognition algorithm presents an accuracy of 91.56%, which resolves the “one person one model” issue along with the difficulty of convergence in the training process.http://dx.doi.org/10.1155/2021/6614677
collection DOAJ
language English
format Article
sources DOAJ
author Xiaofei Zhang
Tao Wang
Qi Xiong
Yina Guo
spellingShingle Xiaofei Zhang
Tao Wang
Qi Xiong
Yina Guo
A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface
Computational Intelligence and Neuroscience
author_facet Xiaofei Zhang
Tao Wang
Qi Xiong
Yina Guo
author_sort Xiaofei Zhang
title A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface
title_short A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface
title_full A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface
title_fullStr A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface
title_full_unstemmed A Dense Long Short-Term Memory Model for Enhancing the Imagery-Based Brain-Computer Interface
title_sort dense long short-term memory model for enhancing the imagery-based brain-computer interface
publisher Hindawi Limited
series Computational Intelligence and Neuroscience
issn 1687-5273
publishDate 2021-01-01
description Imagery-based brain-computer interfaces (BCIs) aim to decode different neural activities into control signals by identifying and classifying various natural commands from electroencephalogram (EEG) patterns and then control corresponding equipment. However, several traditional BCI recognition algorithms have the “one person, one model” issue, where the convergence of the recognition model’s training process is complicated. In this study, a new BCI model with a Dense long short-term memory (Dense-LSTM) algorithm is proposed, which combines the event-related desynchronization (ERD) and the event-related synchronization (ERS) of the imagery-based BCI; model training and testing were conducted with its own data set. Furthermore, a new experimental platform was built to decode the neural activity of different subjects in a static state. Experimental evaluation of the proposed recognition algorithm presents an accuracy of 91.56%, which resolves the “one person one model” issue along with the difficulty of convergence in the training process.
url http://dx.doi.org/10.1155/2021/6614677
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AT taowang adenselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
AT qixiong adenselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
AT yinaguo adenselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
AT xiaofeizhang denselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
AT taowang denselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
AT qixiong denselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
AT yinaguo denselongshorttermmemorymodelforenhancingtheimagerybasedbraincomputerinterface
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