Adaptive threshold to compensate the effect of muscle fatigue on elbow-joint angle estimation based on electromyography

Authors

  • Triwiyanto . Department of Electrical Engineering & Information Technology, Universitas Gadjah Mada, Yogyakarta, Indonesia
  • O. Wahyunggoro1 Department of Electrical Engineering & Information Technology, Universitas Gadjah Mada, Yogyakarta, Indonesia
  • H. A. Nugroho Department of Electrical Engineering & Information Technology, Universitas Gadjah Mada, Yogyakarta, Indonesia
  • Herianto . Department of Mechanical & Industrial Engineering Universitas Gadjah Mada, Yogyakarta, Indonesia

DOI:

https://doi.org/10.15282/jmes.12.3.2018.3.0334

Keywords:

Electromyography, feature extraction, elbow-joint angle estimation, muscle fatigue, low pass filter

Abstract

Muscle fatigue is a major problem in the study based on electromyography (EMG) signal. When the muscle in the fatigue condition, the power of the EMG signal increases significantly. This phenomenon can be a problem in the elbow-joint angle estimation. The purpose of this study is to develop a method in order to compensate the effect of the muscle fatigue on the elbow-joint angle estimation based on time domain features using EMG signal. The EMG signal was collected from biceps while the subjects performed a fatiguing motion of flexion and extension. The EMG was extracted using four time-domain features, namely zero crossing (ZC), sign slope change (SSC), Wilson amplitude (WAMP) and myopulse percentage rate (MYOP). The yielded features were filtered using second order Butterworth low pass filter. In the proposed method, to compensate the effect of the muscle fatigue, the RMS of the EMG signal was calculated for every cycle and used it as a threshold value of the features. The results show that the proposed method is able to compensate the effect of muscle fatigue with a consistent root mean square error (RMSE). The improvement of the performance ranges between 17.41% and 37.9% (for all adaptive features).

References

Nishihara K, Isho T. Location of electrodes in surface EMG. EMG Methods for Evaluating Muscle and Nerve Function, InTech. 2012; 17–30.

Merlo A, Campanini I. Technical aspects of surface electromyography for clinicians. The Open Rehabilitation Journal. 2010; 3: 98–109.

Oskoei MA, Hu H. Myoelectric control systems - a survey. Biomedical Signal Processing and Control. 2007; 2 (4): 275–294.

Antuvan CW, Ison M., and Artemiadis P. Embedded human control of robots using myoelectric interfaces. IEEE Transactions on Neural Systems and Rehabilitation Engineering. 2014; 22 (4): 820–827.

Fougner A, Stavdahl O, Kyberd PJ, Losier YG, Parker PA. Control of upper limb prostheses: terminology and proportional myoelectric control - A review. IEEE Transactions on Neural Systems and Rehabilitation Engineering. 2012; 20 (5): 663–677.

Zhang X, Liu Y, Zhang F, Ren J, Lindsay Y, Yang Q, Huang H. On design and implementation of neural-machine interface for artificial legs. IEEE Transactions on Industrial Informatics. 2012; 8 (2): 418–429.

Chin LC, Nisa bin Basah S, Yaacob S, Juan YE. Conceptual design and implementation for visual tracking ankle rehabilitation system. Journal of Mechanical Engineering and Sciences. 2014; 7: 1208–1218.

Fernini B, Temmar M, Noor M. Toward a dynamic analysis of bipedal robots inspired by human leg muscles. Journal of Mechanical Engineering and Sciences. 2018; 12 (2): 3593–3604.

Rath AK, Das HC, Parhi DR, Kumar PB. Application of artificial neural network for control and navigation of humanoid robot. Journal of Mechanical Engineering and Sciences. 2018; 12 (2): 3529–3538.

Tang Z, Zhang K, Sun S, Gao Z, Zhang L, Yang Z. An upper-limb power-assist exoskeleton using proportional myoelectric control. Sensors. 2014; 14 (4): 6677–6694.

Li Q, Song Y, Hou Z, Zhu B. sEMG based joint angle estimation of lower limbs using LS-SVM. Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics). 2013; 8226 (1): 292–300.

Pau JWL, Xie SSQ, Pullan AJ. Neuromuscular interfacing: establishing an EMG-driven model for the human elbow joint. IEEE Transactions on Biomedical Engineering. 2012; 59 (9): 2586–2593.

Pang M, Guo S, Huang Q, Ishihara H, Hirata H. Electromyography-based quantitative representation method for upper-limb elbow joint angle in sagittal plane. Journal of Medical and Biological Engineering. 2015; 35 (2): 165–177.

Kiguchi K, Hayashi Y. EMG-based control of a lower-limb power-assist robot. Intelligent Assistive Robots. Springer Tracts in Advanced Robotics 106. Springer. 2015; 371–383.

Li Z, Wang B, Sun F, Yang C, Xie Q, Zhang W. SEMG-based joint force control for an upper-limb power-assist exoskeleton robot. IEEE Journal of Biomedical and Health Informatics. 2014; 18 (3): 1043–1050.

Triwiyanto T, Wahyunggoro O, Nugroho H. A, Herianto. An investigation into time domain features of surface electromyography to estimate the elbow joint angle. Advances in Electrical and Electronic Engineering. 2017; 15 (3): 448-458.

Jang G, Kim J, Choi Y, Yim J. Human shoulder motion extraction using EMG signals. International Journal of Precision Engineering and Manufacturing. 2014; 15 (10): 2185–2192.

Triwiyanto T, Wahyunggoro O, Nugroho HA, Herianto H. Evaluating the performance of Kalman filter on elbow joint angle prediction based on electromyography. International Journal of Precision Engineering and Manufacturing. 2017; 18 (12): 1739-1748.

Al-Mulla MR, Sepulveda F, Colley M. sEMG techniques to detect and predict localised muscle fatigue. EMG Methods for Evaluating Muscle and Nerve Function. 2012:1–532.

Basmajian JV, de Luca CJ. Chapter 8. Muscle Fatigue and Time-Dependent Parameters of the Surface EMG Signal. Muscles alive: their functions revealed by electromyography. Baltimore: Williams & Wilkins. 1985; 201–222.

Gonzalez-Izal M, Malanda A, Gorostiaga E, Izquierdo M. Electromyographic models to assess muscle fatigue. Journal of Electromyography and Kinesiology. 2012; 22 (4): 501–512.

Chowdhury SK, Nimbarte AD, Jaridi M, Creese RC. Discrete wavelet transform analysis of surface electromyography for the fatigue assessment of neck and shoulder muscles. Journal of Electromyography and Kinesiology. 2013; 23 (5): 995–1003.

Triwiyanto T, Wahyunggoro O, Nugroho HA, Herianto H. Continuous wavelet transform analysis of surface electromyography for muscle fatigue assessment on the elbow joint motion. Advances in Electrical and Electronic Engineering. 2017; 15 (3): 424-434.

Na Y, Kim J. Dynamic elbow flexion force estimation through a muscle twitch model and sEMG in a fatigue condition. IEEE Transactions on Neural Systems and Rehabilitation Engineering. 2017; 25 (9): 1431–1439.

Lalitharatne TD, Teramoto K, Hayashi Y, Nanayakkara T, Kiguchi K. Evaluation of fuzzy-neuro modifiers for compensation of the effects of muscle fatigue on EMG-based control to be used in upper-limb power-assist exoskeletons. Journal of Advanced Mechanical Design, Systems, and Manufacturing. 2013; 7 (4): 736–751.

Yahya AB, Mohd Bukhari W, Horng CS, Sudirman R. Electromyography signal on biceps muscle in time domain analysis. Journal of Mechanical Engineering and Sciences. 2014; 7: 1179–1188.

Hakonen M, Piitulainen H, Visala A. Biomedical signal processing and control current state of digital signal processing in myoelectric interfaces and related applications. Biomedical Signal Processing and Control. 2015; (18): 334–359.

Triwiyanto T, Wahyunggoro O, Nugroho HA, Herianto H. DWT analysis of sEMG for muscle fatigue assessment of dynamic motion flexion-extension of elbow joint. 8th International Conference on Information Technology and Electrical Engineering (ICITEE), 2016; 1–6.

Martini FH, Ober WC. Fundamentals of Anatomy and Physiology. Englewood Cliffs, New Jersey 7632: Prentice Hall. 1995.

Lenzi T, De Rossi SMM, Vitiello N, Carrozza MC. Intention-based EMG control for powered exoskeletons. IEEE Transactions on Biomedical Engineering. 2012; 59 (8): 2180–2190.

Stegeman D, Hermens H. Standards for surface electromyography: the european project surface EMG for non-invasive assessment of muscles (SENIAM). 2007; 108–112.

Potvin JR. Effects of muscle kinematics on surface EMG amplitude and frequency during fatiguing dynamic contractions. Journal of Applied Physiology. 1997; 82(1): 144–151.

Potvin JR, Bent LR. A validation of techniques using surface EMG signals from dynamic contractions to quantify muscle fatigue during repetitive tasks. Journal of Electromyography and Kinesiology. 1997; 7 (2): 131–139.

Tan L, Jiang J. Digital signal processing: fundamental and applications. Academic Press. 2013.

Hudgins B, Parker P, Scott RN. A new strategy for multifunction myoelectric control. IEEE Transactions on Biomedical Engineering. 1993; 40 (1): 82–94.

Du Y, Lin C, Shyu L, Chen T. Portable hand motion classifier for multi-channel surface electromyography recognition using grey relational analysis. Expert Systems with Applications. 2010; 37 (6): 4283–4291.

Zardoshti-Kermani M, Wheeler BC, Badie K, Hashemi RM. EMG feature evaluation for movement control of upper extremity prostheses. IEEE Transactions on Rehabilitation Engineering. 1995; 3 (4): 324–333.

Fukuda TY, Echeimberg JO, Pompeu JE, Lucareli PRG, Garbelotti S, Gimenes RO, Apolinario A. Root mean square value of the electromyographic signal in the isometric torque of the quadriceps, hamstrings and brachial biceps muscles in female subjects. Journal of Applied Research. 2010; 10 (1): 32–39.

Basmajian J, De Luca CJ. Description and analysis of the EMG signal. Muscles alive: their functions revealed by electromyography. 1985; 65–100.

Al-Mulla MR, Sepulveda F, Al-Bader B. Optimal elbow angle for extracting sEMG signals during fatiguing dynamic contraction. Computers. 2015; 4: 251–264.

Broman H, Bilotto G, De Luca CJ. Myoelectric signal conduction velocity and spectral parameters: influence of force and time. Journal of applied physiology. 1985; 58 (5): 1428–1437.

Yu HJ, Lee AY, Choi Y. Human elbow joint angle estimation using electromyogram signal processing. IET Signal Process. 2011; 5 (8): 767-775.

Yunoh MFM, Abdullah S, Saad MHM, Nopiah ZM, Nuawi MZ. Fatigue feature extraction analysis based on a K-means clustering approach. Journal of Mechanical Engineering and Sciences. 2015; 8: 1275–1282.

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Published

2018-09-30

How to Cite

[1]
T. ., O. Wahyunggoro1, H. A. Nugroho, and H. ., “Adaptive threshold to compensate the effect of muscle fatigue on elbow-joint angle estimation based on electromyography”, J. Mech. Eng. Sci., vol. 12, no. 3, pp. 3786–3796, Sep. 2018.

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