Control and stabilization of cascade coupled systems: application to a 1-d heat and wave coupled system

TL;DR

This paper investigates control and stabilization of a cascade coupled system combining heat and wave equations, establishing well-posedness, controllability, and polynomial stabilization using a structured approach within an abstract framework.

Contribution

It introduces a novel method leveraging the cascade structure to prove controllability and stabilization results for coupled heat-wave systems.

Findings

Proved well-posedness using cascade structure

Achieved simultaneous exact and approximate controllability

Established polynomial stabilization via a Sylvester equation

Abstract

We study cascade coupled systems, for which our prototypical example is a 1-d heat equation coupled with a 1-d wave equation. The heat component is controlled through one boundary and the information is transmitted through another one to the wave component, while the wave component does not influence the heat component. Our aim is to understand the well-posedness, controllability and stabilizability properties for such a system. Establishing well-posedness is tedious using the classical energy method, which motivates us to take advantage of the cascade structure. Taking again advantage of this structure, we prove a simultaneous exact and approximate controllability result. Finally, we obtain polynomial stabilization by means of a closed-loop control defined through the solution to a Sylvester equation. These results are all discussed in an abstract LTI framework and most of our findings apply to more general situations.