Periodically time-varying memory static output feedback control design for discrete-time LTI systems

TL;DR

This paper introduces a novel periodically time-varying memory static output feedback control design for discrete-time LTI systems, utilizing bilinear matrix inequalities and iterative algorithms to improve stabilization strategies.

Contribution

It develops a new BMI-based design framework for periodically time-varying memory SOF controllers, enhancing stabilization methods for discrete-time LTI systems.

Findings

BMI condition can be solved with BMI solvers

Two-step and iterative algorithms improve design process

Example demonstrates effectiveness of the proposed methods

Abstract

This paper addresses the problem of static output feedback (SOF) stabilization for discrete-time LTI systems. We approach this problem using the recently developed periodically time-varying memory state-feedback controller (PTVMSFC) design scheme. A bilinear matrix inequality (BMI) condition which uses a pre-designed PTVMSFC is developed to design the periodically time-varying memory SOF controller (PTVMSOFC). The BMI condition can be solved by using BMI solvers. Alternatively, we can apply two-steps and iterative linear matrix inequality algorithms that alternate between the PTVMSFC and PTVMSOFC designs. Finally, an example is given to illustrate the proposed methods.