A Study on the Low Force Estimation of Skeletal Muscle by using ICA and Neuro-transmission Model

독립성분 분석과 신전달 모델을 이용한 근육의 미세한 힘의 추정에 관한 연구

  • 유세근 (와이더댄(주) 구축팀) ;
  • 염두호 (서울시립대 전자전기컴퓨터공학부) ;
  • 이호용 (서울시립대 전자전기컴퓨터공학부) ;
  • 김성환 (서울시립대 전자전기컴퓨터공학부)
  • Published : 2007.03.01

Abstract

The low force estimation method of skeletal muscle was proposed by using ICA(independent component analysis) and neuro-transmission model. An EMG decomposition is the procedure by which the signal is classified into its constituent MUAP(motor unit action potential). The force index of electromyography was due to the generation of MUAP. To estimate low force, current analysis technique, such as RMS(root mean square) and MAV(mean absolute value), have not been shown to provide direct measures of the number and timing of motoneurons firing or their firing frequencies, but are used due to lack of other options. In this paper, the method based on ICA and chemical signal transmission mechanism from neuron to muscle was proposed. The force generation model consists of two linear, first-order low pass filters separated by a static non-linearity. The model takes a modulated IPI(inter pulse interval) as input and produces isometric force as output. Both the step and random train were applied to the neuro-transmission model. As a results, the ICA has shown remarkable enhancement by finding a hidden MAUP from the original superimposed EMG signal and estimating accurate IPI. And the proposed estimation technique shows good agreements with the low force measured comparing with RMS and MAV method to the input patterns.

Keywords

References

  1. J.V. Basmajian and C.J. DE Luca, Muscle alive, London: Williams & Wilkins, 1985
  2. P.A.M. Griep, K.L. Boon and D.F. Stegeman, 'A study of the motor unit action potential by means of computer simulation,' Bio. Cybernetics, vol. 30, pp. 221-230, 1978 https://doi.org/10.1007/BF00361043
  3. E.A Clancy and N. Hogan, 'Theoretic and experimental comparison of root-mean-square and mean-absolute-value electromyogram amplitude detectors,' in proc. of 19th int conf. of IEEE in Medicine and Biology Society, pp.1267-1270, Oct., 1997
  4. E. Shwedyk, R. Balasubramanian and R.N. Scott, 'A nonstationary model for the electromyogram,' IEEE Trans. on Biomed. Eng., vol. 24, no. 5, pp. 417-424, Aug. 1977 https://doi.org/10.1109/TBME.1977.326175
  5. E.A. Clancy, S. Bouchard and D. Rancourt, 'Estimation and application of EMG amplitude during dynamic contractions,' IEEE Eng. in Medicine and Biology, pp. 47-54, Nov./lDec., 2001
  6. J. Bobet and R. B. Stein, 'A Simple Model of Force Generation by Skeletal Muscle During Dynamic Isometric Contraction'. IEEE Trans. on Biomedical Eng., Vol. 45, No.8, pp. 1010-1016, August 1998 https://doi.org/10.1109/10.704869
  7. A. Cichocki and S.I. Amari., Adaptive Blind Signal and Image Processing, Wiley, 2002
  8. A. Hyvarine, J. Karhunen and E. Oja, Independent Component Analysis, Wiley Interscience 2001
  9. P. Zhou, W. Z. Rymer, N. Suresh and L. Zhang, 'A Study of suface motor unit action potential in first dorsal interosseous (fdi) muscle,' 23rd Annual EMBS International Conf., pp. 1074-1077, 2001
  10. D. L. Donoho, 'Denoising by Soft Thresholding,' IEEE Tans. on Info. Theory vol. 41, pp. 613-627, 1995 https://doi.org/10.1109/18.382009
  11. A. Hyvarine, J. Karhunen and E. Oja, Independent Component Analysis, Wiley Interscience 2001