Separable least squares identification of a parallel cascade model of human ankle stiffness [stretch reflex EMG]

Author

Westwick, David T. ; Kearney, Robert E.

Author_Institution

Dept. Elec. & Comp. Eng., Calgary Univ., Alta., Canada

Volume

2

fYear

2001

fDate

2001

Firstpage

1282

Abstract

The identification of a dynamic, nonlinear model of human ankle stiffness is considered in a minimum mean squared error framework. The model consists of two parallel pathways, one representing the intrinsic dynamics, the other representing the reflex contribution to the stiffness. The model is shown to be linear in all of its parameters, except for those used to describe a single static nonlinearity in the reflex pathway. A separable least squares optimization algorithm is developed which takes advantage of this structure. This new algorithm is applied to experimental stretch reflex data, and the results compared to the current state-of-the-art algorithm, an iterative technique which fits the two pathways alternately. The relative merits of the two approaches are discussed.

Keywords

biomechanics; cascade systems; dynamics; electromyography; identification; iterative methods; least squares approximations; mean square error methods; optimisation; physiological models; dynamic nonlinear model; human ankle stiffness; intrinsic dynamics; minimum mean squared error framework; parallel cascade model; reflex; separable least squares identification; separable least squares optimization algorithm; stretch reflex EMG; Biomedical measurements; Humans; Integrated circuit modeling; Iterative algorithms; Least squares methods; Linear systems; Nonlinear dynamical systems; Nonlinear systems; System identification; Torque;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society, 2001. Proceedings of the 23rd Annual International Conference of the IEEE

ISSN

1094-687X

Print_ISBN

0-7803-7211-5

Type

conf

DOI

10.1109/IEMBS.2001.1020429

Filename

1020429