DocumentCode
1457108
Title
Identification of electrically stimulated quadriceps muscles in paraplegic subjects
Author
Chizeck, Howard Jay ; Chang, Seokjoo ; Stein, Richard B. ; Scheiner, Avram ; Ferencz, Donald C.
Author_Institution
Motion Study Lab., Cleveland V.A. Med. Center, OH, USA
Volume
46
Issue
1
fYear
1999
Firstpage
51
Lastpage
61
Abstract
This work establishes a method for the noninvasive in vivo identification of parametric models of electrically stimulated muscle in paralyzed individuals, when significant inertial loads and/or load transitions are present. The method used differs from earlier work, in that both the pulse width and stimulus period (interpulse interval) modulation are considered. A Hill-type time series model, in which the output is the product of two factors (activation and torque-angle) is used. In this coupled model, the activation dynamics depend upon velocity. Sequential nonlinear least squares methods are used in the parameter identification. The ability of the model, using identified time-varying parameters, to accurately predict muscle torque outputs is evaluated, along with the variability of the identified parameters. This technique can be used to determine muscle parameter models for biomechanical computer simulations, and for real-time adaptive control and monitoring of muscle response variations such as fatigue.
Keywords
bioelectric phenomena; biomechanics; neuromuscular stimulation; parameter estimation; physiological models; Hill-type time series model; coupled model; electrically stimulated quadriceps muscles identification; fatigue; inertial loads; interpulse interval; load transitions; muscle response variations; parameter identification; parametric models; paraplegic subjects; pulse width; sequential nonlinear least squares methods; torque-angle; Computer simulation; In vivo; Least squares methods; Muscles; Parameter estimation; Parametric statistics; Predictive models; Pulse width modulation; Space vector pulse width modulation; Torque; Algorithms; Biomechanics; Electric Stimulation; Female; Humans; Leg; Linear Models; Male; Muscle Contraction; Muscle, Skeletal; Paraplegia; Signal Processing, Computer-Assisted; Torque;
fLanguage
English
Journal_Title
Biomedical Engineering, IEEE Transactions on
Publisher
ieee
ISSN
0018-9294
Type
jour
DOI
10.1109/10.736755
Filename
736755
Link To Document