Robust synchronization for multi-agent systems governed by PDEs with observable and unobservable disturbances

TL;DR

This paper develops a robust boundary control and disturbance estimation framework for multi-agent PDE systems, ensuring synchronization and disturbance rejection even with unobservable disturbances, validated through simulations.

Contribution

It introduces a boundary disturbance observer and distributed controllers for PDE-governed MASs, achieving robust synchronization with ISS guarantees under unobservable disturbances.

Findings

Effective disturbance estimation and rejection demonstrated in simulations

Robust synchronization achieved with unobservable disturbances present

ISS properties established for the closed-loop system

Abstract

This paper investigates robust synchronization for multi-agent systems (MASs) governed by parabolic partial differential equations in the presence of both observable and unobservable disturbances. Using only boundary output measurements, a disturbance observer is designed to estimate observable Dirichlet boundary disturbances while ensuring robustness of the observer error system with unobservable disturbances occurring in the domain. Using only the reference signal and local output information, distributed synchronization controllers are then constructed to enable all agents to track the reference trajectory. In particular, exponential tracking is achieved in the absence of unobservable disturbances, while robustness is preserved when additional unobservable disturbances occur during controller implementation. We further analyze the impact of unobservable Dirichlet-Robin boundary disturbances on synchronization performance by proving the boundedness of solutions to the synchronization error system. Moreover, to characterize the influence of all disturbances, input-to-state stability (ISS) is established for the closed-loop system. For the involved systems, the generalized Lyapunov method and the recursion technique are extensively employed in the stability analysis, and the lifting technique and semigroup theory are used to prove the well-posedness. Simulation results validate the proposed control scheme, demonstrating effective disturbance estimation and rejection, robust synchronization, and the ISS properties under various scenarios.