Robust nonfragile observer-based H2/H∞ controller

A robust nonfragile observer-based controller for a linear time-invariant system with structured uncertainty is introduced. The H ∞ robust stability of the closed-loop system is guaranteed by use of the Lyapunov theorem in the presence of undesirable disturbance. For the sake of addressing the fragi...

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Bibliographic Details
Published in:Journal of vibration and control 2018-02, Vol.24 (4), p.722-738
Main Authors: Oveisi, Atta, Nestorović, Tamara
Format: Article
Language:English
Subjects:
Automatic control
Closed loop systems
Control systems
Control systems design
Disturbance
Fragility
Functions (mathematics)
H-infinity control
Mathematical analysis
Mathematical models
Matrix methods
Optimization
Real time
Reduced order models
Robust control
Robustness (mathematics)
Time invariant systems
Uncertainty
Vibration
Vibration control
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Summary:A robust nonfragile observer-based controller for a linear time-invariant system with structured uncertainty is introduced. The H ∞ robust stability of the closed-loop system is guaranteed by use of the Lyapunov theorem in the presence of undesirable disturbance. For the sake of addressing the fragility problem, independent sets of time-dependent gain-uncertainties are assumed to be existing for the controller and the observer elements. In order to satisfy the arbitrary H2-normed constraints for the control system and to enable automatic determination of the optimal H 2 / H ∞ bound of the performance functions in disturbance rejection control, additional necessary and sufficient conditions are presented in a linear matrix equality/inequality framework. The H 2 / H ∞ observer-based controller is then transformed into an optimization problem of coupled set of linear matrix equalities/inequality that can be solved iteratively by use of numerical software such as Scilab. Finally, concerning the evaluation of the performance of the controller, the control system is implemented in real time on a mechanical system, aiming at vibration suppression. The plant under study is a multi-input single-output clamped-free piezo-laminated smart beam. The nominal mathematical reduced-order model of the beam with piezo-actuators is used to design the proposed controller and then the control system is implemented experimentally on the full-order real-time system. The results show that the closed-loop system has a robust performance in rejecting the disturbance in the presence of the structured uncertainty and in the presence of the unmodeled dynamics.
ISSN:1077-5463
1741-2986
DOI:10.1177/1077546316651548