Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning

Deep metric learning (DML) has achieved state-of-the-art results in several deep learning applications. However, this type of deep learning models has not been tested on the classification of electrical brain waves (EEG) for brain computer interface (BCI) applications. For the first time, we propose...

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Main Authors: Alwasiti, H., Yusoff, M.Z., Raza, K.
Format: Article
Published: Institute of Electrical and Electronics Engineers Inc. 2020
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85087279627&doi=10.1109%2fACCESS.2020.3002459&partnerID=40&md5=131d21e15985a293397fc8e33731293c
http://eprints.utp.edu.my/23225/
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spelling my.utp.eprints.232252021-08-19T06:09:12Z Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning Alwasiti, H. Yusoff, M.Z. Raza, K. Deep metric learning (DML) has achieved state-of-the-art results in several deep learning applications. However, this type of deep learning models has not been tested on the classification of electrical brain waves (EEG) for brain computer interface (BCI) applications. For the first time, we propose a triplet network to classify motor imagery (MI) EEG signals. Stockwell Transform has been used for converting the EEG signals in the time domain into the frequency domain, which resulted in improved DML classification accuracy in comparison to DML with Short Term Fourier Transform (0.647 vs. 0.431). DML model was trained with a topogram of concatenated 64 EEG channel spectrograms. The training batch was comprised of triplet pairs of the anchor, positive, and negative labeled epochs. The triplet network was able to train an embedding feature space that minimized the Euclidean distance between the embeddings of spectrograms of the same class and increased the distance between the embeddings of different labeled images. The proposed method has been tested on an EEG dataset of 109 untrained subjects. We showed that the DML classifier is able to converge with an extremely small number of training samples ( 120 EEG trials) for only one subject per model, mitigating the well-known issue of the large inter-individual variability of human MI-BCI EEG which degrades the classification performance. The proposed preprocessing pipeline and the Triplet Network provide a promising method to classify MI-BCI EEG signals with much less training samples than the previous methods. © 2013 IEEE. Institute of Electrical and Electronics Engineers Inc. 2020 Article NonPeerReviewed https://www.scopus.com/inward/record.uri?eid=2-s2.0-85087279627&doi=10.1109%2fACCESS.2020.3002459&partnerID=40&md5=131d21e15985a293397fc8e33731293c Alwasiti, H. and Yusoff, M.Z. and Raza, K. (2020) Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning. IEEE Access, 8 . pp. 109949-109963. http://eprints.utp.edu.my/23225/
institution Universiti Teknologi Petronas
building UTP Resource Centre
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Petronas
content_source UTP Institutional Repository
url_provider http://eprints.utp.edu.my/
description Deep metric learning (DML) has achieved state-of-the-art results in several deep learning applications. However, this type of deep learning models has not been tested on the classification of electrical brain waves (EEG) for brain computer interface (BCI) applications. For the first time, we propose a triplet network to classify motor imagery (MI) EEG signals. Stockwell Transform has been used for converting the EEG signals in the time domain into the frequency domain, which resulted in improved DML classification accuracy in comparison to DML with Short Term Fourier Transform (0.647 vs. 0.431). DML model was trained with a topogram of concatenated 64 EEG channel spectrograms. The training batch was comprised of triplet pairs of the anchor, positive, and negative labeled epochs. The triplet network was able to train an embedding feature space that minimized the Euclidean distance between the embeddings of spectrograms of the same class and increased the distance between the embeddings of different labeled images. The proposed method has been tested on an EEG dataset of 109 untrained subjects. We showed that the DML classifier is able to converge with an extremely small number of training samples ( 120 EEG trials) for only one subject per model, mitigating the well-known issue of the large inter-individual variability of human MI-BCI EEG which degrades the classification performance. The proposed preprocessing pipeline and the Triplet Network provide a promising method to classify MI-BCI EEG signals with much less training samples than the previous methods. © 2013 IEEE.
format Article
author Alwasiti, H.
Yusoff, M.Z.
Raza, K.
spellingShingle Alwasiti, H.
Yusoff, M.Z.
Raza, K.
Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning
author_facet Alwasiti, H.
Yusoff, M.Z.
Raza, K.
author_sort Alwasiti, H.
title Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning
title_short Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning
title_full Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning
title_fullStr Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning
title_full_unstemmed Motor Imagery Classification for Brain Computer Interface Using Deep Metric Learning
title_sort motor imagery classification for brain computer interface using deep metric learning
publisher Institute of Electrical and Electronics Engineers Inc.
publishDate 2020
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85087279627&doi=10.1109%2fACCESS.2020.3002459&partnerID=40&md5=131d21e15985a293397fc8e33731293c
http://eprints.utp.edu.my/23225/
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score 13.211869