Affiliation:
1. Department of Electrical Engineering and Applied Physics and Center for Automation and Intelligent Systems Research, Case Western Reserve University, Cleveland, Ohio 44106
Abstract
A technique is presented for controlling second-order, nonlinear systems using a combination of bang-bang time-optimal control, sliding-mode control, and feedback linearization. Within the control loop, a state space evaluation of the system classifies the instantaneous dynamics into one of three regions, and one of three corresponding control algorithms is invoked. Using a prescribed generation of desirable sliding surfaces, the resulting combined controller produces nearly time-optimal performance. The combination controller is provably stable in the presence of model uncertainty. Experimental data are presented for the control of a General Electric GP132 industrial robot. The method is shown to achieve nearly time-optimal motion that is robust to modeling uncertainties. Representative transients compare favorably to bang-bang control and PD control.
Subject
Computer Science Applications,Mechanical Engineering,Instrumentation,Information Systems,Control and Systems Engineering
Cited by
16 articles.
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1. Sub-Optimal Control for Nonlinear Heat Equations;Applied Mechanics and Materials;2012-11
2. Near-time-optimal tracking controller design for an automotive electromechanical brake;Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering;2011-11-18
3. Minimum time control of a second-order system;49th IEEE Conference on Decision and Control (CDC);2010-12
4. An Improved 2-DOF Proximate Time Optimal Servomechanism;IEEE Transactions on Magnetics;2009-05
5. Discrete-Time Sliding Mode Control With Time-Varying Surface for Hard Disk Drives;IEEE Transactions on Control Systems Technology;2009-01