Cooperative output regulation for a network of parabolic systems with varying parameters

TL;DR

This paper develops a systematic control approach for a network of parabolic PDE agents with varying parameters, achieving cooperative output regulation and synchronization despite disturbances.

Contribution

It introduces a backstepping-based method for cooperative regulation of heterogeneous parabolic systems with time-varying parameters and disturbances.

Findings

Achieved exponential convergence in cooperative output regulation.

Designed local output feedback regulators for parabolic agents.

Validated approach on a network of four heterogeneous parabolic agents.

Abstract

This paper is concerned with the cooperative output regulation problem for a network of agents with different dynamics described by parabolic PDEs subject to spatially- and time-varying parameters. Firstly, a networked controller is designed achieving output synchronization for identical finite-dimensional reference models, which deliver the state of the global reference model required for the synchronization to the parabolic agents. The latter can be subject to local disturbances acting in-domain, on all boundaries and on the anti-collocated output to be controlled. The cooperative output regulation problem is solved by designing local output feedback regulators for the parabolic agents. This requires the solution of time-varying regulator equations and the design of disturbance observers for parabolic systems with spatially- and time-varying coefficients. For this, a systematic backstepping approach is provided and it is shown that cooperative output regulation with exponential convergence is ensured for the resulting multi-agent system. The results of the paper are applied to the cooperative output regulation of a heterogeneous network of four parabolic agents in the presence of local disturbances.