Title :
Tremor suppression through impedance control
Author :
Pledgie, Stephen ; Barner, Kenneth E. ; Agrawal, Sunil K. ; Rahman, Tariq
Author_Institution :
Biomechanics & Movement Sci. Program, Delaware Univ., Newark, DE, USA
fDate :
3/1/2000 12:00:00 AM
Abstract :
This paper presents a method for designing tremor suppression systems that achieve a specified reduction in pathological tremor power through controlling the impedance of the human-machine interface. Position, rate, and acceleration feedback are examined and two techniques for the selection of feedback coefficients are discussed. Both techniques seek a desired closed-loop human-machine frequency response and require the development of open-loop human-machine models through system identification. The design techniques were used to develop a tremor suppression system that was subsequently evaluated using human subjects. It is concluded that nonadaptive tremor suppression systems that utilize impedance control to achieve a specified reduction in tremor power can be successfully designed when accurate open-loop human-machine models are available
Keywords :
autoregressive moving average processes; biocontrol; closed loop systems; feedback; frequency response; identification; motion control; physiological models; transfer functions; acceleration feedback; closed-loop human-machine frequency response; discrete-time ARMA; human-machine interface; impedance control; open-loop human-machine models; pathological tremor power; position feedback; rate feedback; rehabilitation; system identification; target-tracking tasks; transfer function; tremor suppression systems; Acceleration; Control systems; Design methodology; Feedback; Frequency response; Impedance; Man machine systems; Open loop systems; Pathology; Power system modeling;
Journal_Title :
Rehabilitation Engineering, IEEE Transactions on
