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Volume 22, Issue 3 (Autumn 2020)
Advances in Cognitive Sciences 2020, 22(3): 95-104 |
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Ebrahimi H, Shalbaf A, Jafarnia Dabanloo N. Classification of right and left-hand motor imagery using deep learning inelectroencephalography and near-infrared spectroscopy. Advances in Cognitive Sciences 2020; 22 (3) :95-104
URL: http://icssjournal.ir/article-1-1119-en.html
URL: http://icssjournal.ir/article-1-1119-en.html
1- Department of Biomedical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
2- Department of Biomedical Engineering and Medical Physics, School of Medicine, Shahid Beheshti University of Medical Sciences, Tehran, Iran
2- Department of Biomedical Engineering and Medical Physics, School of Medicine, Shahid Beheshti University of Medical Sciences, Tehran, Iran
Abstract: (2500 Views)
Introduction: In this paper, a hybrid brain-computer interface for classification of right and left hand motor imagery using deep learning method is presented to increase accuracy and performance. A hybrid brain-computer interface is designed to achieve a way of communicating between the brain and an external device for patients such as amyotrophic lateral sclerosis. So, the user can control the external device such as a Wheelchair without using any organs of the body and only using brain.
Methods: Two electroencephalographic and near-infrared spectroscopy signals were recorded from 29 healthy men and women and pre-processing of the signals was done to eliminate noise. The wavelet transform was used to obtain the scalogram as two-dimensional images for both of the signals, and images were inserted separately from each region of brain and merge region into the pre-trained convolutional neural network to extract feature, classification, and prediction of left and right hand motor imagery.
Results: The results for combination of scalogram images of Frontal-Central and Central-Parietal regions in electroencephalographic signal reached 88%, for Near infrared light spectroscopy reached 85% and for merge of two scalogram images reached 90%.
Conclusion: The combination of scalogram images and the deep learning method used in this study reached significant improvement in the prediction accuracy of right and left hand motor imagery for wheelchair motion control.
Methods: Two electroencephalographic and near-infrared spectroscopy signals were recorded from 29 healthy men and women and pre-processing of the signals was done to eliminate noise. The wavelet transform was used to obtain the scalogram as two-dimensional images for both of the signals, and images were inserted separately from each region of brain and merge region into the pre-trained convolutional neural network to extract feature, classification, and prediction of left and right hand motor imagery.
Results: The results for combination of scalogram images of Frontal-Central and Central-Parietal regions in electroencephalographic signal reached 88%, for Near infrared light spectroscopy reached 85% and for merge of two scalogram images reached 90%.
Conclusion: The combination of scalogram images and the deep learning method used in this study reached significant improvement in the prediction accuracy of right and left hand motor imagery for wheelchair motion control.
Keywords: Brain-Computer Interface, Electroencephalography, Near Infrared Light Spectroscopy, Convolutional Neural Network
Type of Study: Research |
Received: 2020/04/20 | Accepted: 2020/07/14 | Published: 2020/10/1
Received: 2020/04/20 | Accepted: 2020/07/14 | Published: 2020/10/1
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