Title :
Guaranteed stability of haptic systems with nonlinear virtual environments
Author :
Miller, Brian E. ; Colgate, J. Edward ; Freeman, Randy A.
Author_Institution :
Comput. Motion Inc., Goleta, CA, USA
fDate :
12/1/2000 12:00:00 AM
Abstract :
Design of haptic systems that guarantee stable interaction is a challenging task. Virtual environments are typically highly nonlinear-resulting in a nonpassive discrete-time model. This paper will investigate how nonlinear mass/spring/damper virtual environments can be designed to guarantee the absence of oscillations and other chaotic behavior in the signal presented to the human operator. In particular, delayed and nondelayed implementation of the mass/spring/damper virtual environment is considered, revealing a nonintuitive result with regard to the allowable local stiffness
Keywords :
discrete time systems; haptic interfaces; nonlinear systems; stability; allowable local stiffness; chaotic behavior; delayed implementation; guaranteed stability; haptic system design; nondelayed implementation; nonlinear mass/spring/damper virtual environments; nonpassive discrete-time model; oscillations; Chaos; Damping; Delay; Haptic interfaces; Humans; Shock absorbers; Signal design; Springs; Stability; Virtual environment;
Journal_Title :
Robotics and Automation, IEEE Transactions on
