English

Constrained nonlinear output regulation using model predictive control -- extended version

Systems and Control 2021-06-02 v3 Systems and Control Optimization and Control

Abstract

We present a model predictive control (MPC) framework to solve the constrained nonlinear output regulation problem. The main feature of the proposed framework is that the application does not require the solution to classical regulator (Francis-Byrnes-Isidori) equations or any other offline design procedure. In particular, the proposed formulation simply minimizes the predicted output error, possibly with some input regularization. Instead of using terminal cost/sets or a positive definite stage cost as is standard in MPC theory, we build on the theoretical results by Grimm et al. 2005 using a detectability notion. The proposed formulation is applicable if the constrained nonlinear regulation problem is (strictly) feasible, the plant is incrementally stabilizable and incrementally input-output to state stable (i-IOSS/detectable). We show that for minimum phase systems such a design ensures exponential stability of the regulator manifold. We also provide a design procedure in case of unstable zero dynamics using an incremental input regularization and a nonresonance condition. Inherent robustness properties for the noisy error/output-feedback case are established under simplifying assumptions (e.g. no state constraints). The theoretical results are illustrated with an example involving offset free tracking with noisy error feedback. The paper also contains novel results for MPC without terminal constraints with positive semidefinite input/output stage costs that are of independent interest.

Keywords

Cite

@article{arxiv.2005.12413,
  title  = {Constrained nonlinear output regulation using model predictive control -- extended version},
  author = {Johannes Köhler and Matthias A. Müller and Frank Allgöwer},
  journal= {arXiv preprint arXiv:2005.12413},
  year   = {2021}
}

Comments

Extended version of accepted paper in Transaction on Automatic Control, 2021. Contains the following additional results: Exponential bounds on the suboptimality index using an observability condition and an extension of the derived theory to the noisy error feedback case

R2 v1 2026-06-23T15:48:19.986Z