Title :
Feedback control of unsupported standing in paraplegia. I. Optimal control approach
Author :
Hunt, Kenneth J. ; Munih, Marko ; Donaldson, Nick De N
Author_Institution :
Daimler-Benz AG, Berlin, Germany
fDate :
12/1/1997 12:00:00 AM
Abstract :
This is the first of a pair of papers which describe an investigation into the feasibility of providing artificial balance to paraplegics using electrical stimulation of the paralyzed muscles. By bracing the body above the shanks, only stimulation of the plantarflexors is necessary. This arrangement prevents any influence from the intact neuromuscular system above the spinal cord lesion. Here, the authors extend the design of the controllers to a nested-loop LQG (linear quadratic Gaussian) stimulation controller which has ankle moment feedback (inner loops) and inverted pendulum angle feedback (outer loop). Each control loop is tuned by two parameters, the control weighting and an observer rise-time, which together determine the behavior. The nested structure was chosen because it is robust, despite changes in the muscle properties (fatigue) and interference from spasticity
Keywords :
biocontrol; biomechanics; feedback; muscle; neurophysiology; optimal control; orthotics; ankle moment feedback; artificial balance; body bracing; control loop; electrical stimulation; feedback control; inverted pendulum angle feedback; muscle fatigue; muscle properties; nested structure; nested-loop linear quadratic Gaussian stimulation controller; optimal control approach; paralyzed muscles; paraplegia; plantarflexors; spasticity interference; spinal cord lesion; unsupported standing; Electrical stimulation; Feedback control; Feedback loop; Lesions; Linear feedback control systems; Muscles; Neurofeedback; Neuromuscular; Spinal cord; Weight control;
Journal_Title :
Rehabilitation Engineering, IEEE Transactions on
