Motor Imagery Electroencephalogram Feature Selection Algorithm Based on Mutual Information and Principal Component Analysis_Journal of Biomedical Engineering

Authors：

XUJialin ,  ZUOGuokun

Ningbo Institute of Materials Technology and Engineering, CAS, Ningbo 315201, China;

Corresponding author：

ZUOGuokun, Email: moonstone@nimte.ac.cn

Keywords：

brain-computer interface; motor imagery electroencephalogram; feature selection; mutual information; principal component analysis

DOI：

10.7507/1001-5515.20160036

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Aiming at feature selection problem of motor imagery task in brain computer interface (BCI), an algorithm based on mutual information and principal component analysis (PCA) for electroencephalogram (EEG) feature selection is presented. This algorithm introduces the category information, and uses the sum of mutual information matrices between features under different motor imagery category to replace the covariance matrix. The eigenvectors of the sum matrix represent the direction of the principal components and the eigenvalues of the sum matrix are used to determine the dimensionality of principal components. 2005 International BCI competition data set was used in our experiments, and four feature extraction methods were adopted, i. e. power spectrum estimation, continuous wavelet transform, wavelet packet decomposition and Hjorth parameters. The proposed feature selection algorithm was adopted to select and combine the most useful features for classification. The results showed that relative to the PCA algorithm, our algorithm had better performance in dimensionality reduction and in classification accuracy with the assistance of support vector machine classifier under the same dimensionality of principal components.

Citation： XUJialin, ZUOGuokun. Motor Imagery Electroencephalogram Feature Selection Algorithm Based on Mutual Information and Principal Component Analysis. Journal of Biomedical Engineering, 2016, 33(2): 201-207. doi: 10.7507/1001-5515.20160036 Copy

1.	WOLPAW J R, BIRBAUMER N, HEETDERKS W J, et al. Brain-computer interface technology:a review of the first international meeting[J]. IEEE Trans Rehabil Eng, 2000, 8(2):164-173.
2.	CHEN Guangyi. Automatic EEG seizure detection using dual-tree complex wavelet-Fourier features[J]. Expert Syst Appl, 2014, 41(5):2391-2394.
3.	GHANBARI A A, KOUSARRIZI M R N, TESHNEHLAB M, et al. Wavelet and Hilbert transform-based brain computer interface[C]//Proceedings of the International Conference on Advances in Computational Tools for Engineering Applications. Zouk Mosbeh:2009:438-442.
4.	WAN B K, LIU Y G, MING D, et al. Feature recognition of multi-class imaginary movements in brain computer interface[C]//Proceedings of the International Conference on Virtual Environments, Human-Computer Interfaces and Measurements Systems. Hongkong:2009:250-254.
5.	PFURTSCHELLER G, LOPES DA SILVA F H. Event-related EEG/MEG synchronization and desynchronization:basic principles[J]. Clin Neurophysiol, 1999, 110(11):1842-1857.
6.	MILLÁN JDEL R, MOURIÑO J. Asynchronous BCI and local neural classifiers:an overview of the Adaptive Brain Interface project[J]. IEEE Trans Neural Syst Rehabil Eng, 2003, 11(2):159-161.
7.	CHANDRASHEKAR G, SAHIN F. A survey on feature selection methods[J]. Computers and Electrical Engineering, 2014, 40(1):16-28.
8.	JOLLIFFE I T. Principal component analysis[M]. New York:Springer, 1986:10-28.
9.	ARVANEH M, GUAN C, ANG K K, et al. Mutual information-based optimization of sparse spatio-spectral filters in brain-computer interface[J]. Neural Computing and Applications, 2014, 25(3-4):625-634.
10.	SHANNON C E. A mathematical theory of communication[J]. ACM Sigmobile Mobile Computing and Communications Review, 2001, 5(1):3-55.
11.	SCHLOGL A, GRAIMANN B, PFURTSCHELLER G. BCI Competition III[EB/OL]. http://www.bbci.de/competition/iii/, 2005.
12.	BASHASHATI A, FATOURECHI M, WARD R K, et al. A survey of signal processing algorithms in brain-computer interfaces based on electrical brain signals[J]. J Neural Eng, 2007, 4(2):R32-R57.
13.	RODRÍGUEZ-BERMÚDEZ G, GARCÍA-LAENCINA P J. Automatic and adaptive classification of electroencephalographic signals for brain computer interfaces[J]. J Med Syst, 2012, 36(Suppl 1):S51-S63.
14.	CORRALEJO R, HORNERO R, ALVAREZ D. Feature selection using a genetic algorithm in a motor imagery-based brain computer interface[C]//Proceedings of the International Conference on Engineering in Medicine and Biology Society. Boston:2011:7703-7706.
15.	HETTIARACHCHI I T, NGUYEN T T, NAHAVANDI S. Motor imagery data classification for BCI application using wavelet packet feature extraction[C]//Proceedings of 21st International Conference on Neural Information Processing. Kuching:2014:519-526.
16.	VIDAURRE C, KRÄMER N, BLANKERTZ B, et al. Time domain parameters as a feature for EEG-based Brain-Computer Interfaces[J]. Neural Netw, 2009, 22(9):1313-1319.
17.	徐宝国,宋爱国,费树岷.在线脑机接口中脑电信号的特征提取与分类方法[J].电子学报,2011,39(5):1025-1030.

1. WOLPAW J R, BIRBAUMER N, HEETDERKS W J, et al. Brain-computer interface technology:a review of the first international meeting[J]. IEEE Trans Rehabil Eng, 2000, 8(2):164-173.
2. CHEN Guangyi. Automatic EEG seizure detection using dual-tree complex wavelet-Fourier features[J]. Expert Syst Appl, 2014, 41(5):2391-2394.
3. GHANBARI A A, KOUSARRIZI M R N, TESHNEHLAB M, et al. Wavelet and Hilbert transform-based brain computer interface[C]//Proceedings of the International Conference on Advances in Computational Tools for Engineering Applications. Zouk Mosbeh:2009:438-442.
4. WAN B K, LIU Y G, MING D, et al. Feature recognition of multi-class imaginary movements in brain computer interface[C]//Proceedings of the International Conference on Virtual Environments, Human-Computer Interfaces and Measurements Systems. Hongkong:2009:250-254.
5. PFURTSCHELLER G, LOPES DA SILVA F H. Event-related EEG/MEG synchronization and desynchronization:basic principles[J]. Clin Neurophysiol, 1999, 110(11):1842-1857.
6. MILLÁN JDEL R, MOURIÑO J. Asynchronous BCI and local neural classifiers:an overview of the Adaptive Brain Interface project[J]. IEEE Trans Neural Syst Rehabil Eng, 2003, 11(2):159-161.
7. CHANDRASHEKAR G, SAHIN F. A survey on feature selection methods[J]. Computers and Electrical Engineering, 2014, 40(1):16-28.
8. JOLLIFFE I T. Principal component analysis[M]. New York:Springer, 1986:10-28.
9. ARVANEH M, GUAN C, ANG K K, et al. Mutual information-based optimization of sparse spatio-spectral filters in brain-computer interface[J]. Neural Computing and Applications, 2014, 25(3-4):625-634.
10. SHANNON C E. A mathematical theory of communication[J]. ACM Sigmobile Mobile Computing and Communications Review, 2001, 5(1):3-55.
11. SCHLOGL A, GRAIMANN B, PFURTSCHELLER G. BCI Competition III[EB/OL]. http://www.bbci.de/competition/iii/, 2005.
12. BASHASHATI A, FATOURECHI M, WARD R K, et al. A survey of signal processing algorithms in brain-computer interfaces based on electrical brain signals[J]. J Neural Eng, 2007, 4(2):R32-R57.
13. RODRÍGUEZ-BERMÚDEZ G, GARCÍA-LAENCINA P J. Automatic and adaptive classification of electroencephalographic signals for brain computer interfaces[J]. J Med Syst, 2012, 36(Suppl 1):S51-S63.
14. CORRALEJO R, HORNERO R, ALVAREZ D. Feature selection using a genetic algorithm in a motor imagery-based brain computer interface[C]//Proceedings of the International Conference on Engineering in Medicine and Biology Society. Boston:2011:7703-7706.
15. HETTIARACHCHI I T, NGUYEN T T, NAHAVANDI S. Motor imagery data classification for BCI application using wavelet packet feature extraction[C]//Proceedings of 21st International Conference on Neural Information Processing. Kuching:2014:519-526.
16. VIDAURRE C, KRÄMER N, BLANKERTZ B, et al. Time domain parameters as a feature for EEG-based Brain-Computer Interfaces[J]. Neural Netw, 2009, 22(9):1313-1319.
17. 徐宝国,宋爱国,费树岷.在线脑机接口中脑电信号的特征提取与分类方法[J].电子学报,2011,39(5):1025-1030.

Next Article
Three-class Motor Imagery Classification Based on Optimal Sub-band Features of Independent Components

Journal of Biomedical Engineering

Motor Imagery Electroencephalogram Feature Selection Algorithm Based on Mutual Information and Principal Component Analysis

Abstract Full text Figures/Tables Video References Cited by

Next Article

Format

Content