A Hierarchical Surrogate Model for Efficient Multi-Task Parameter Learning in Closed-Loop Control
Abstract
Many control problems require repeated tuning and adaptation of controllers across distinct closed-loop tasks, where data efficiency and adaptability are critical. We propose a hierarchical Bayesian optimization (BO) framework that is tailored to efficient controller parameter learning in sequential decision-making and control scenarios for distinct tasks. Instead of treating the closed-loop cost as a black-box, our method exploits structural knowledge of the underlying problem, consisting of a dynamical system, a control law, and an associated closed-loop cost function. We construct a hierarchical surrogate model using Gaussian processes that capture the closed-loop state evolution under different parameterizations, while the task-specific weighting and accumulation into the closed-loop cost are computed exactly via known closed-form expressions. This allows knowledge transfer and enhanced data efficiency between different closed-loop tasks. The proposed framework retains sublinear regret guarantees on par with standard black-box BO, while enabling multi-task or transfer learning. Simulation experiments with model predictive control demonstrate substantial benefits in both sample efficiency and adaptability when compared to purely black-box BO approaches.
Cite
@article{arxiv.2508.12738,
title = {A Hierarchical Surrogate Model for Efficient Multi-Task Parameter Learning in Closed-Loop Control},
author = {Sebastian Hirt and Lukas Theiner and Maik Pfefferkorn and Rolf Findeisen},
journal= {arXiv preprint arXiv:2508.12738},
year = {2026}
}
Comments
8 pages, 4 figures, accepted for CDC 2025