A Novel Spatial Feature for the Identification of Motor Tasks Using High-Density Electromyography

Estimation of neuromuscular intention using electromyography (EMG) and pattern recognition is still an open problem. One of the reasons is that the pattern-recognition approach is greatly influenced by temporal changes in electromyograms caused by the variations in the conductivity of the skin and/or electrodes, or physiological changes such as muscle fatigue. This paper proposes novel features for task identification extracted from the high-density electromyographic signal (HD-EMG) by applying the mean shift channel selection algorithm evaluated using a simple and fast classifier-linear discriminant analysis. HD-EMG was recorded from eight subjects during four upper-limb isometric motor tasks (flexion/extension, supination/pronation of the forearm) at three different levels of effort. Task and effort level identification showed very high classification rates in all cases. This new feature performed remarkably well particularly in the identification at very low effort levels. This could be a step towards the natural control in everyday applications where a subject could use low levels of effort to achieve motor tasks. Furthermore, it ensures reliable identification even in the presence of myoelectric fatigue and showed robustness to temporal changes in EMG, which could make it suitable in long-term applications.

[1]  Dario Farina,et al.  Improving the Robustness of Myoelectric Pattern Recognition for Upper Limb Prostheses by Covariate Shift Adaptation , 2016, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[2]  Guy Lapalme,et al.  A systematic analysis of performance measures for classification tasks , 2009, Inf. Process. Manag..

[3]  Dario Farina,et al.  Decoding the neural drive to muscles from the surface electromyogram , 2010, Clinical Neurophysiology.

[4]  Levi J. Hargrove,et al.  A Comparison of Surface and Intramuscular Myoelectric Signal Classification , 2007, IEEE Transactions on Biomedical Engineering.

[5]  He Huang,et al.  Spatial Filtering Improves EMG Classification Accuracy Following Targeted Muscle Reinnervation , 2009, Annals of Biomedical Engineering.

[6]  Frederick Mosteller,et al.  A $k$-Sample Slippage Test for an Extreme Population , 1948 .

[7]  Monica Rojas-Martínez,et al.  High-density surface EMG maps from upper-arm and forearm muscles , 2012, Journal of NeuroEngineering and Rehabilitation.

[8]  Erik Scheme,et al.  Training Strategies for Mitigating the Effect of Proportional Control on Classification in Pattern Recognition–Based Myoelectric Control , 2013, Journal of prosthetics and orthotics : JPO.

[9]  Larry D. Hostetler,et al.  The estimation of the gradient of a density function, with applications in pattern recognition , 1975, IEEE Trans. Inf. Theory.

[10]  J. F. Alonso,et al.  Identification of isometric contractions based on High Density EMG maps. , 2013, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[11]  Kevin C. McGill,et al.  Electromyographic (EMG) Decomposition , 2016 .

[12]  Oluwarotimi Williams Samuel,et al.  A motion-classification strategy based on sEMG-EEG signal combination for upper-limb amputees , 2017, Journal of NeuroEngineering and Rehabilitation.

[13]  Fionn Murtagh,et al.  Handbook of Cluster Analysis , 2015 .

[14]  Dario Farina,et al.  The Extraction of Neural Information from the Surface EMG for the Control of Upper-Limb Prostheses: Emerging Avenues and Challenges , 2014, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[15]  B Hudgins,et al.  Myoelectric signal processing for control of powered limb prostheses. , 2006, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[16]  T. Sejnowski,et al.  Closed-Loop Brain–Machine–Body Interfaces for Noninvasive Rehabilitation of Movement Disorders , 2014, Annals of Biomedical Engineering.

[17]  Yu Hu,et al.  Surface EMG-Based Inter-Session Gesture Recognition Enhanced by Deep Domain Adaptation , 2017, Sensors.

[18]  S. Qin,et al.  Selection of the Number of Principal Components: The Variance of the Reconstruction Error Criterion with a Comparison to Other Methods† , 1999 .

[19]  T. Kuiken,et al.  Quantifying Pattern Recognition—Based Myoelectric Control of Multifunctional Transradial Prostheses , 2010, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[20]  Xinjun Sheng,et al.  Invariant Surface EMG Feature Against Varying Contraction Level for Myoelectric Control Based on Muscle Coordination , 2015, IEEE Journal of Biomedical and Health Informatics.

[21]  Raoul M. Bongers,et al.  Learning an EMG Controlled Game: Task-Specific Adaptations and Transfer , 2016, PloS one.

[22]  Guanglin Li,et al.  Principal Components Analysis Preprocessing for Improved Classification Accuracies in Pattern-Recognition-Based Myoelectric Control , 2009, IEEE Transactions on Biomedical Engineering.

[23]  Roberto Merletti,et al.  Technology and instrumentation for detection and conditioning of the surface electromyographic signal: state of the art. , 2009, Clinical biomechanics.

[24]  Ali Ameri,et al.  A comparison between force and position control strategies in myoelectric prostheses , 2012, 2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[25]  E. Parzen On Estimation of a Probability Density Function and Mode , 1962 .

[26]  M. Mansourian,et al.  A Hybrid Computer-aided-diagnosis System for Prediction of Breast Cancer Recurrence (HPBCR) Using Optimized Ensemble Learning , 2016, Computational and structural biotechnology journal.

[27]  Roberto Merletti,et al.  Automatic segmentation of surface EMG images: Improving the estimation of neuromuscular activity. , 2010, Journal of biomechanics.

[28]  K. Roeleveld,et al.  Inhomogeneities in muscle activation reveal motor unit recruitment. , 2005, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[29]  T. Cacoullos Estimation of a multivariate density , 1966 .

[30]  Dario Farina,et al.  Proportional estimation of finger movements from high-density surface electromyography , 2016, Journal of NeuroEngineering and Rehabilitation.

[31]  H. Hermens,et al.  SENIAM 8: European recommendations for surface electromyography , 1999 .

[32]  Nurhazimah Nazmi,et al.  A Review of Classification Techniques of EMG Signals during Isotonic and Isometric Contractions , 2016, Sensors.

[33]  D. Reinkensmeyer,et al.  Review of control strategies for robotic movement training after neurologic injury , 2009, Journal of NeuroEngineering and Rehabilitation.

[34]  Dorin Comaniciu,et al.  Mean Shift: A Robust Approach Toward Feature Space Analysis , 2002, IEEE Trans. Pattern Anal. Mach. Intell..

[35]  Dennis C. Tkach,et al.  Study of stability of time-domain features for electromyographic pattern recognition , 2010, Journal of NeuroEngineering and Rehabilitation.

[36]  Huosheng Hu,et al.  Myoelectric control systems - A survey , 2007, Biomed. Signal Process. Control..

[37]  Antanas Verikas,et al.  Electromyographic Patterns during Golf Swing: Activation Sequence Profiling and Prediction of Shot Effectiveness , 2016, Sensors.

[38]  Weidong Geng,et al.  Gesture recognition by instantaneous surface EMG images , 2016, Scientific Reports.

[39]  Arto Visala,et al.  urrent state of digital signal processing in myoelectric interfaces and elated applications , 2015 .

[40]  Miguel Angel Mañanas,et al.  Spatial distribution of HD-EMG improves identification of task and force in patients with incomplete spinal cord injury , 2016, Journal of NeuroEngineering and Rehabilitation.

[41]  Yuan-Ting Zhang,et al.  A novel channel selection method for multiple motion classification using high-density electromyography , 2014, BioMedical Engineering OnLine.

[42]  Dario Farina,et al.  Detection of Multiple Innervation Zones from Multi-Channel Surface EMG Recordings with Low Signal-to-Noise Ratio Using Graph-Cut Segmentation , 2016, PloS one.

[43]  Lucas C. Parra,et al.  Concurrent Adaptation of Human and Machine Improves Simultaneous and Proportional Myoelectric Control , 2015, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[44]  D Farina,et al.  Electromyographic mapping of the erector spinae muscle with varying load and during sustained contraction. , 2009, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[45]  Klaus-Robert Müller,et al.  Spatial Filtering for Robust Myoelectric Control , 2012, IEEE Transactions on Biomedical Engineering.

[46]  Xinjun Sheng,et al.  Towards Zero Retraining for Myoelectric Control Based on Common Model Component Analysis , 2016, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[47]  Gaël Varoquaux,et al.  Scikit-learn: Machine Learning in Python , 2011, J. Mach. Learn. Res..

[48]  Chun-Yi Su,et al.  Boosting-Based EMG Patterns Classification Scheme for Robustness Enhancement , 2013, IEEE Journal of Biomedical and Health Informatics.

[49]  Blair A. Lock,et al.  Adaptive Pattern Recognition of Myoelectric Signals: Exploration of Conceptual Framework and Practical Algorithms , 2009, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[50]  Miguel Angel Mañanas,et al.  Prediction of isometric motor tasks and effort levels based on high-density EMG in patients with incomplete spinal cord injury , 2016, Journal of neural engineering.