Abstract
Herein, robust pole placement controller design for linear uncertain discrete time dynamic systems is addressed. The adopted approach uses the so called “D regions” where the closed loop system poles are determined to lie. The discrete time pole regions corresponding to the prescribed damping of the resulting closed loop system are studied. The key issue is to determine the appropriate convex approximation to the originally non-convex discrete-time system pole region, so that numerically efficient robust controller design algorithms based on Linear Matrix Inequalities (LMI) can be used. Several alternatives for relatively simple inner approximations and their corresponding LMI descriptions are presented. The developed LMI region for the prescribed damping can be arbitrarily combined with other LMI pole limitations (e.g., stability degree). Simple algorithms to calculate the matrices for LMI representation of the proposed convex pole regions are provided in a concise way. The results and their use in a robust controller design are illustrated on a case study of a laboratory magnetic levitation system.
Highlights
Analysis and control of linear dynamic systems have reached the mature stage in control system theory
The paper provides the thorough study of discrete-time pole regions appropriate for a robust pole placement controller design
The main problem is finding adequate and computationally simple inner convex approximation for the nonconvex discrete-time system pole region corresponding to the prescribed damping
Summary
Analysis and control of linear dynamic systems have reached the mature stage in control system theory. When the continuous-time system is considered, the pole regions related to the prescribed stability degree and relative damping (which belong to the basic performance indices closely connected, e.g., with overshoot, rise time, settling time, and decay rate) are convex and can be formulated by LMI or DR regions [4,5,6,9] This is not the case for the discrete-time counterpart, where the prescribed relative damping corresponds to the non-convex pole region. This paper provides the comprehensive survey of various DR pole regions corresponding to basic closed loop performance indices and detailed descriptions (algorithms) of all the proposed inner approximations for a discrete-time system pole region with prescribed damping and their comparison. The results are illustrated by the example—pole placement for a laboratory magnetic levitation plant
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