Stabilization of Integral Delay Equations by solving Fredholm equations

TL;DR

This paper introduces a new stabilizing control law for integral delay systems using Fredholm equations, ensuring stability under spectral controllability, and extends to cases with only distributed control.

Contribution

It presents a novel, simpler method for stabilizing integral delay equations via Fredholm equations, applicable to both pointwise and distributed delays, with broader cases covered.

Findings

Closed-loop stability is guaranteed with the proposed controller.

Existence of solutions is ensured under spectral controllability.

Method extends to cases with only distributed control under regularity assumptions.

Abstract

In this paper, we design a stabilizing state-feedback control law for a system represented by a general class of integral delay equations subject to a pointwise and distributed input delay. The proposed controller is defined in terms of integrals of the state and input history over a fixed-length time window. We show that the closed-loop stability is guaranteed, provided the controller integral kernels are solutions to a set of Fredholm equations. The existence of solutions is guaranteed under an appropriate spectral controllability assumption, resulting in an implementable stabilizing control law. The proposed methodology appears simpler and more general compared to existing results in the literature. In particular, under additional regularity assumptions, the proposed approach can be expanded to address the degenerate case where only a distributed control term is present.