Input-to-State Stability of a Clamped-Free Damped String in the Presence of Distributed and Boundary Disturbances

TL;DR

This paper proves exponential input-to-state stability for a damped string with boundary and distributed disturbances, using a novel projection method to overcome challenges in boundary disturbance analysis.

Contribution

It introduces a new approach using Riesz basis projections to establish EISS for boundary disturbances in a damped string system.

Findings

Established EISS for boundary disturbances in a damped string

Developed a projection method using Riesz basis

Overcame limitations of traditional lifting operator techniques

Abstract

This note establishes the Exponential Input-to-State Stability (EISS) property for a clamped-free damped string with respect to distributed and boundary disturbances. While efficient methods for establishing ISS properties for distributed parameter systems with respect to distributed disturbances have been developed during the last decades, establishing ISS properties with respect to boundary disturbances remains challenging. One of the well-known methods for well-posedness analysis of systems with boundary inputs is the use of a lifting operator for transferring the boundary disturbance to a distributed one. However, the resulting distributed disturbance involves time derivatives of the boundary perturbation. Thus, the subsequent ISS estimate depends on its amplitude, and may not be expressed in the strict form of ISS properties. To solve this problem, we show for a clamped-free damped string equation that the projection of the original system trajectories in an adequate Riesz basis can be used to establish the desired EISS property.