Design of a Gait Phase Recognition System That Can Cope With EMG Electrode Location Variation

Electromyogram (EMG) signal-based gait phase recognition for walking-assist devices warrants much attention in human-centered system design as it well exemplifies human-in-the-loop control where the system's prediction directly affects subsequent walking motion. Since walking motion poses considerable variations in electrode placement, performance reliability of such systems is contingent on a combination of electrode montage and a feature extraction method that takes into account underlying physiological factors of peripheral muscles where electrodes are placed. In many practical applications, however, proper consideration of effects of the electrode location variation on performance reliability of the system has received scant empirical attention. Here, based on a user-centered design principle, we establish a gait phase recognition system that is capable of rigidly controlling ill effects due to this covariate by carrying out a large-scale analysis that combines statistical, model-based, and empirical approaches. In doing so, we have developed a special sensing suit for the control of electrode placement and a reliable data acquisition. We then have conducted a nonparametric statistical analysis on class separability values of thirty types of EMG feature sets, followed by a model-based analysis to address the tradeoff between class separability and dimensionality. To further address the issue of how these results generalize to independent systems and data sets, we have carried out an empirical performance assessment over six classification methods. First, the two feature types, Integral of Absolute Value and Histogram, and a combination of the two are shown to be robust against electrode location variations while providing a firm performance guarantee. Second, system organization scenarios are presented on a case-by-case basis, allowing us to trade off system complexity for on-line adaptation capability. Collectively, our integrated analysis lends itself to formulating a guideline for design of highly reliable EMG signal-based walking assistant systems in a variety of smart home scenarios.

[1]  H. Devries MUSCLES ALIVE-THEIR FUNCTIONS REVEALED BY ELECTROMYOGRAPHY , 1976 .

[2]  Yoshiyuki Sankai,et al.  Power assist control for walking aid with HAL-3 based on EMG and impedance adjustment around knee joint , 2002, IEEE/RSJ International Conference on Intelligent Robots and Systems.

[3]  Richard O. Duda,et al.  Pattern classification and scene analysis , 1974, A Wiley-Interscience publication.

[4]  Z. Zenn Bien,et al.  Applying human learning principles to user-centered IoT systems , 2013, Computer.

[5]  Patrick K. Simpson,et al.  Fuzzy min-max neural networks. I. Classification , 1992, IEEE Trans. Neural Networks.

[6]  Nello Cristianini,et al.  Kernel Methods for Pattern Analysis , 2004 .

[7]  Tao Jiang,et al.  Efficient and robust feature extraction by maximum margin criterion , 2003, IEEE Transactions on Neural Networks.

[8]  B.H. Jansen,et al.  Multidimensional EMG-based assessment of walking dynamics , 2003, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[9]  J. Perry,et al.  Pattern recognition of multiple EMG signals applied to the description of human gait , 1977, Proceedings of the IEEE.

[10]  Zeung nam Bien Multi-Resolution Fuzzy Min-Max Neural Network with On-line Learning Ability Using Mixture of Experts , 2004 .

[11]  Sanjeev R. Kulkarni,et al.  An Elementary Introduction to Statistical Learning Theory: Kulkarni/Statistical Learning Theory , 2011 .

[12]  D. Farina,et al.  Effect of joint angle on EMG variables in leg and thigh muscles , 2001, IEEE Engineering in Medicine and Biology Magazine.

[13]  Satoru Kuhara,et al.  Recursive gene selection based on maximum margin criterion: a comparison with SVM-RFE , 2006, BMC Bioinformatics.

[14]  Vladimir Vapnik,et al.  Statistical learning theory , 1998 .

[15]  Fuhui Long,et al.  Feature selection based on mutual information criteria of max-dependency, max-relevance, and min-redundancy , 2003, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[16]  Z. Zenn Bien,et al.  Feature subset selection using separability index matrix , 2013, Inf. Sci..

[17]  L Guidetti,et al.  EMG patterns during running: Intra- and inter-individual variability. , 1996, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[18]  Jan Rueterbories,et al.  Methods for gait event detection and analysis in ambulatory systems. , 2010, Medical engineering & physics.

[19]  Masoud Nikravesh,et al.  Feature Extraction: Foundations and Applications (Studies in Fuzziness and Soft Computing) , 2006 .

[20]  Sanjeev R. Kulkarni,et al.  An Elementary Introduction to Statistical Learning Theory , 2011 .

[21]  Ilya Levner,et al.  Feature selection and nearest centroid classification for protein mass spectrometry , 2005, BMC Bioinformatics.

[22]  Z. Bien,et al.  Walking Phase Recognition for People with Lower Limb Disability , 2007, 2007 IEEE 10th International Conference on Rehabilitation Robotics.

[23]  Gabriel Curio,et al.  MACHINE LEARNING TECHNIQUES FOR BRAIN-COMPUTER INTERFACES , 2004 .

[24]  Bruce C. Wheeler,et al.  EMG feature evaluation for movement control of upper extremity prostheses , 1995 .

[25]  Günter Hommel,et al.  Predicting the intended motion with EMG signals for an exoskeleton orthosis controller , 2005, 2005 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[26]  Roberto Battiti,et al.  Using mutual information for selecting features in supervised neural net learning , 1994, IEEE Trans. Neural Networks.

[27]  Z. Zenn Bien,et al.  Robust EMG pattern recognition to muscular fatigue effect for powered wheelchair control , 2009, J. Intell. Fuzzy Syst..

[28]  Lauren H Smith,et al.  A comparison of the real-time controllability of pattern recognition to conventional myoelectric control for discrete and simultaneous movements , 2012, Journal of NeuroEngineering and Rehabilitation.

[29]  A. Berlinet,et al.  Reproducing kernel Hilbert spaces in probability and statistics , 2004 .

[30]  Z. Zenn Bien,et al.  Feature Subset Selection of Biosignals for Rehabilitation System , 2006 .

[31]  H. Kawamoto,et al.  Power assist method for HAL-3 using EMG-based feedback controller , 2003, SMC'03 Conference Proceedings. 2003 IEEE International Conference on Systems, Man and Cybernetics. Conference Theme - System Security and Assurance (Cat. No.03CH37483).

[32]  Brian T. Smith,et al.  Application of a neuro-fuzzy network for gait event detection using electromyography in the child with Cerebral palsy , 2005, IEEE Transactions on Biomedical Engineering.

[33]  Jason Weston,et al.  Gene Selection for Cancer Classification using Support Vector Machines , 2002, Machine Learning.

[34]  Mohammad Hassan Moradi,et al.  Evaluation of the forearm EMG signal features for the control of a prosthetic hand. , 2003, Physiological measurement.

[35]  Yoshiyuki Sankai,et al.  Power assist control for leg with HAL-3 based on virtual torque and impedance adjustment , 2002, IEEE International Conference on Systems, Man and Cybernetics.

[36]  Michael A. Peshkin,et al.  A Highly Backdrivable, Lightweight Knee Actuator for Investigating Gait in Stroke , 2009, IEEE Transactions on Robotics.

[37]  Vojislav Kecman,et al.  Kernel Based Algorithms for Mining Huge Data Sets: Supervised, Semi-supervised, and Unsupervised Learning , 2006, Studies in Computational Intelligence.

[38]  Z. Zenn Bien,et al.  A Study on Performance Improvement of Fuzzy Min-Max Neural Network Using Gating Network , 2003 .

[39]  Jong-Tae Lim,et al.  Robotic smart house to assist people with movement disabilities , 2007, Auton. Robots.

[40]  Jeong SuHan,et al.  Feature Selection of EMG Signals Based on The Separability Matrix and Rough Set Theory , 2005 .

[41]  Sheldon M. Ross,et al.  Introduction to probability models , 1975 .

[42]  P. K. Simpson Fuzzy Min-Max Neural Networks-Part 1 : Classification , 1992 .