Micro-Macro Backstepping Control of Large-Scale Hyperbolic Systems (Extended Version)
Abstract
We introduce a control design and analysis framework for micro-macro, boundary control of large-scale, hyperbolic PDE systems. Specifically, we develop feedback laws for stabilization of hyperbolic systems at the micro level (i.e., of the large-scale system) that employ a) measurements obtained from the system (i.e., at micro level) and kernels constructed based on an continuum system counterpart (i.e., at macro level), or b) kernels and measurements both stemming from a continuum counterpart, or c) averaged-continuum kernels/measurements. We also address (d)) stabilization of the continuum (macro) system, employing continuum kernels and measurements. Towards addressing d) we derive in a constructive manner an continuum approximation of hyperbolic systems and establish that its solutions approximate, for large and , the solutions of the system. We then construct a feedback law for stabilization of the system via introduction of a continuum-PDE backstepping transformation. We establish well-posedness of the resulting 4-D kernel equations and prove closed-loop stability via construction of a novel Lyapunov functional. Furthermore, under control configuration a) we establish that the closed-loop system is exponentially stable provided that and are large, by proving that the exact, stabilizing control kernels can be accurately approximated by the continuum kernels. While under control configurations b) and c), we establish closed-loop stability capitalizing on the established solutions' and kernels' approximation properties via employment of infinite-dimensional ISS arguments. We provide two numerical simulation examples to illustrate the effectiveness and potential limitations of our design approach.
Cite
@article{arxiv.2510.12456,
title = {Micro-Macro Backstepping Control of Large-Scale Hyperbolic Systems (Extended Version)},
author = {Jukka-Pekka Humaloja and Nikolaos Bekiaris-Liberis},
journal= {arXiv preprint arXiv:2510.12456},
year = {2025}
}
Comments
22 pages, 5 figures