A Generalized, Frequency Domain-Embedded, State Space Approach for Controller Synthesis

Abstract

This paper develops a novel control synthesis approach for a wide class of practical systems. The control action is derived by inserting a compensator device in the forward path of the system that is to be controlled. The compensator design method is based on a state space system that is embedded in the frequency domain of the plant. It uses a nonlinear subspace that is the image of the compensator being used to determine the parameters of the compensator and modify system behavior. The coordinates of the state space system are taken as the compensator parameters. The method is capable of designing a compensator of arbitrary order to make the system comply with given stability performance requirements provided that these requirements can be geometrically interpreted in the frequency domain. The approach is developed and a proof of its ability to converge, if a solution exists, to the compensator tuning parameter set that satisfy the desired performance conditions is provided. A set of design examples are supplied to demonstrate the applicability of the approach to different types of linear, nonlinear, SISO and MIMO systems and system with delays.