Learning Common Time-Frequency-Spatial Patterns for Motor Imagery Classification

The common spatial patterns (CSP) algorithm is the most popular spatial filtering method applied to extract electroencephalogram (EEG) features for motor imagery (MI) based brain-computer interface (BCI) systems. The effectiveness of the CSP algorithm depends on optimal selection of the frequency band and time window from the EEG. Many algorithms have been designed to optimize frequency band selection for CSP, while few algorithms seek to optimize the time window. This study proposes a novel framework, termed common time-frequency-spatial patterns (CTFSP), to extract sparse CSP features from multi-band filtered EEG data in multiple time windows. Specifically, the whole MI period is first segmented into multiple subseries using a sliding time window approach. Then, sparse CSP features are extracted from multiple frequency bands in each time window. Finally, multiple support vector machine (SVM) classifiers with the Radial Basis Function (RBF) kernel are trained to identify the MI tasks and the voting result of these classifiers determines the final output of the BCI. This study applies the proposed CTFSP algorithm to three public EEG datasets (BCI competition III dataset IVa, BCI competition III dataset IIIa, and BCI competition IV dataset 1) to validate its effectiveness, compared against several other state-of-the-art methods. The experimental results demonstrate that the proposed algorithm is a promising candidate for improving the performance of MI-BCI systems.

[1]  Tiago H. Falk,et al.  Deep learning-based electroencephalography analysis: a systematic review , 2019, Journal of neural engineering.

[2]  E Donchin,et al.  Brain-computer interface technology: a review of the first international meeting. , 2000, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[3]  Gernot R. Müller-Putz,et al.  Control of an Electrical Prosthesis With an SSVEP-Based BCI , 2008, IEEE Transactions on Biomedical Engineering.

[4]  R. Tibshirani Regression Shrinkage and Selection via the Lasso , 1996 .

[5]  Ping Xue,et al.  Sub-band Common Spatial Pattern (SBCSP) for Brain-Computer Interface , 2007, 2007 3rd International IEEE/EMBS Conference on Neural Engineering.

[6]  Ian Daly,et al.  Internal Feature Selection Method of CSP Based on L1-Norm and Dempster–Shafer Theory , 2020, IEEE Transactions on Neural Networks and Learning Systems.

[7]  Hyun-Chul Kim,et al.  Constructing support vector machine ensemble , 2003, Pattern Recognit..

[8]  Ludmila I. Kuncheva,et al.  A Theoretical Study on Six Classifier Fusion Strategies , 2002, IEEE Trans. Pattern Anal. Mach. Intell..

[9]  Rifai Chai,et al.  Driver Fatigue Classification With Independent Component by Entropy Rate Bound Minimization Analysis in an EEG-Based System , 2017, IEEE Journal of Biomedical and Health Informatics.

[10]  Qin Tang,et al.  L1-Norm-Based Common Spatial Patterns , 2012, IEEE Transactions on Biomedical Engineering.

[11]  Yijun Wang,et al.  Enhance decoding of pre-movement EEG patterns for Brain-Computer Interfaces. , 2019, Journal of neural engineering.

[12]  Yang Yu,et al.  Toward brain-actuated car applications: Self-paced control with a motor imagery-based brain-computer interface , 2016, Comput. Biol. Medicine.

[13]  Klaus-Robert Müller,et al.  A regularized discriminative framework for EEG analysis with application to brain–computer interface , 2010, NeuroImage.

[14]  Cuntai Guan,et al.  Regularizing Common Spatial Patterns to Improve BCI Designs: Unified Theory and New Algorithms , 2011, IEEE Transactions on Biomedical Engineering.

[15]  H. Zou,et al.  Regularization and variable selection via the elastic net , 2005 .

[16]  Ning Jiang,et al.  Reduce brain computer interface inefficiency by combining sensory motor rhythm and movement-related cortical potential features , 2020, Journal of neural engineering.

[17]  Xinjun Sheng,et al.  Common Spatial Pattern with Polarity Check for reducing delay latency in detection of MRCP based BCI system , 2017, 2017 8th International IEEE/EMBS Conference on Neural Engineering (NER).

[18]  Howida A. Shedeed,et al.  A CSP\AM-BA-SVM Approach for Motor Imagery BCI System , 2018, IEEE Access.

[19]  Xingyu Wang,et al.  An ERP-based BCI with peripheral stimuli: validation with ALS patients , 2020, Cognitive Neurodynamics.

[20]  Reinhold Scherer,et al.  FORCe: Fully Online and Automated Artifact Removal for Brain-Computer Interfacing , 2015, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[21]  James C. Bezdek,et al.  Decision templates for multiple classifier fusion: an experimental comparison , 2001, Pattern Recognit..

[22]  Xingyu Wang,et al.  Sparse Bayesian Learning for Obtaining Sparsity of EEG Frequency Bands Based Feature Vectors in Motor Imagery Classification , 2017, Int. J. Neural Syst..

[23]  Ning Jiang,et al.  Enhanced Low-Latency Detection of Motor Intention From EEG for Closed-Loop Brain-Computer Interface Applications , 2014, IEEE Transactions on Biomedical Engineering.

[24]  G. Pfurtscheller,et al.  The BCI competition III: validating alternative approaches to actual BCI problems , 2006, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[25]  S J Schiff,et al.  Performance predictors of brain–computer interfaces in patients with amyotrophic lateral sclerosis , 2016, Journal of neural engineering.

[26]  Rongrong Fu,et al.  Automated Detection of Driver Fatigue Based on Entropy and Complexity Measures , 2014, IEEE Transactions on Intelligent Transportation Systems.

[27]  M Congedo,et al.  A review of classification algorithms for EEG-based brain–computer interfaces: a 10 year update , 2018, Journal of neural engineering.

[28]  M Hallett,et al.  Movement-related cortical potentials. , 1994, Electromyography and clinical neurophysiology.

[29]  Gary E. Birch,et al.  Sparse spatial filter optimization for EEG channel reduction in brain-computer interface , 2008, 2008 IEEE International Conference on Acoustics, Speech and Signal Processing.

[30]  Bernhard Schölkopf,et al.  Support vector channel selection in BCI , 2004, IEEE Transactions on Biomedical Engineering.

[31]  Chuang Lin,et al.  Endogenous sensory discrimination and selection by a fast brain switch for a high transfer rate brain-computer interface , 2016, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[32]  Gert Pfurtscheller,et al.  Motor imagery and direct brain-computer communication , 2001, Proc. IEEE.

[33]  Xingyu Wang,et al.  Optimizing spatial patterns with sparse filter bands for motor-imagery based brain–computer interface , 2015, Journal of Neuroscience Methods.

[34]  Xingyu Wang,et al.  Towards correlation-based time window selection method for motor imagery BCIs , 2018, Neural Networks.

[35]  G. Pfurtscheller,et al.  Optimal spatial filtering of single trial EEG during imagined hand movement. , 2000, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[36]  Ugur Halici,et al.  A novel deep learning approach for classification of EEG motor imagery signals , 2017, Journal of neural engineering.

[37]  Jinglu Hu,et al.  A novel frequency band selection method for Common Spatial Pattern in Motor Imagery based Brain Computer Interface , 2010, The 2010 International Joint Conference on Neural Networks (IJCNN).

[38]  Shuicheng Yan,et al.  Learning Temporal Information for Brain-Computer Interface Using Convolutional Neural Networks , 2018, IEEE Transactions on Neural Networks and Learning Systems.

[39]  Chiew Tong Lau,et al.  A New Discriminative Common Spatial Pattern Method for Motor Imagery Brain–Computer Interfaces , 2009, IEEE Transactions on Biomedical Engineering.

[40]  Yu Zhang,et al.  Sparse Group Representation Model for Motor Imagery EEG Classification , 2019, IEEE Journal of Biomedical and Health Informatics.

[41]  Urbano Nunes,et al.  Statistical spatial filtering for a P300-based BCI: Tests in able-bodied, and patients with cerebral palsy and amyotrophic lateral sclerosis , 2011, Journal of Neuroscience Methods.

[42]  K. Jellinger,et al.  The Bereitschaftspotential: Movement Related Cortical Potentials , 2003 .

[43]  Xingyu Wang,et al.  Temporally Constrained Sparse Group Spatial Patterns for Motor Imagery BCI , 2019, IEEE Transactions on Cybernetics.

[44]  Jie Li,et al.  Evaluation and Application of a Hybrid Brain Computer Interface for Real Wheelchair Parallel Control with Multi-Degree of Freedom , 2014, Int. J. Neural Syst..

[45]  Ad Aertsen,et al.  Review of the BCI Competition IV , 2012, Front. Neurosci..

[46]  Xingyu Wang,et al.  Improved RCSP and AdaBoost-based classification for Motor-Imagery BCI , 2019, 2019 IEEE International Conference on Computational Intelligence and Virtual Environments for Measurement Systems and Applications (CIVEMSA).

[47]  Jianjun Meng,et al.  Optimizing spatial spectral patterns jointly with channel configuration for brain-computer interface , 2013, Neurocomputing.

[48]  A. Cichocki,et al.  BCI-Based Rehabilitation on the Stroke in Sequela Stage , 2020, Neural plasticity.

[49]  Chih-Jen Lin,et al.  LIBSVM: A library for support vector machines , 2011, TIST.

[50]  Haiping Lu,et al.  Regularized Common Spatial Pattern With Aggregation for EEG Classification in Small-Sample Setting , 2010, IEEE Transactions on Biomedical Engineering.

[51]  Cuntai Guan,et al.  Filter Bank Common Spatial Pattern (FBCSP) in Brain-Computer Interface , 2008, 2008 IEEE International Joint Conference on Neural Networks (IEEE World Congress on Computational Intelligence).

[52]  Cuntai Guan,et al.  Filter Bank Common Spatial Pattern Algorithm on BCI Competition IV Datasets 2a and 2b , 2012, Front. Neurosci..