Estimates of Acausal Joint Impedance Models

Estimates of joint or limb impedance are commonly used in the study of how the nervous system controls posture and movement, and how that control is altered by injury to the neural or musculoskeletal systems. Impedance characterizes the dynamic relationship between an imposed perturbation of joint p...

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Bibliographic Details
Published in:IEEE transactions on biomedical engineering 2012-10, Vol.59 (10), p.2913-2921
Main Authors: Westwick, David. T., Perreault, Eric J.
Format: Article
Language:English
Subjects:
Algorithms
Ankle Joint - physiology
Applied sciences
Biomechanical Phenomena
Detection, estimation, filtering, equalization, prediction
Discrete-time
Elbow Joint - physiology
Electric Impedance
Exact sciences and technology
Fourier Analysis
Humans
Impedance
Information, signal and communications theory
joint dynamics
Joints
Models, Biological
Noise
parametric model
Position measurement
sampling
Sampling, quantization
Servomotors
Signal and communications theory
Signal, noise
Signal-To-Noise Ratio
Statistics, Nonparametric
system identification
Telecommunications and information theory
time domain
Time domain analysis
Torque
two-sided impulse response
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Summary:Estimates of joint or limb impedance are commonly used in the study of how the nervous system controls posture and movement, and how that control is altered by injury to the neural or musculoskeletal systems. Impedance characterizes the dynamic relationship between an imposed perturbation of joint position and the torques generated in response. While there are many practical reasons for estimating impedance rather than its inverse, admittance, it is an acausal representation of the limb mechanics that can lead to difficulties in interpretation or use. The purpose of this study was to explore the acausal nature of nonparametric estimates of joint impedance representations to determine how they are influenced by common experimental and computational choices. This was accomplished by deriving discrete-time realizations of first- and second-order derivatives to illustrate two key difficulties in the physical interpretation of impedance impulse response functions. These illustrations were provided using both simulated and experimental data. It was found that the shape of the impedance impulse response depends critically on the selected sampling rate, and on the bandwidth and noise characteristics of the position perturbation used during the estimation process. These results provide important guidelines for designing experiments in which nonparametric estimates of impedance will be obtained, especially when those estimates are to be used in a multistep identification process.
ISSN:0018-9294
1558-2531
DOI:10.1109/TBME.2012.2213339