On Persistently Resetting Learning Integrators: A Framework For Model-Free Feedback Optimization

Abstract

We study a novel class of algorithms for solving model-free feedback optimization problems in dynamical systems. The key novelty is the introduction of persistent resetting learning integrators (PRLI), which are integrators that are reset at the same frequency at which the plant is dithered using exploratory signals for model-free optimization. It is shown that PRLIs can serve as core mechanisms for real-time gradient estimation in online feedback-optimization tasks where only cost function measurements are available. In particular, unlike existing approaches based on approximation theory, such as averaging or finite-differences, PRLIs can produce global real-time gradient estimates of cost functions, with uniformly bounded perturbations of arbitrarily small magnitude. In this sense, PRLIs function as robust hybrid "Oracles" suitable for interconnection with discrete-time optimization algorithms that optimize the performance of continuous-time dynamical plants in closed-loop operation. Compared to existing methods, PRLIs yield global stability properties for a broad class of cost functions, surpassing the local or semi-global guarantees offered by traditional approaches based on perturbation and approximation theory. The proposed framework naturally bridges physical systems, modeled as continuous-time plants where continuous exploration is essential, with digital algorithms, represented as discrete-time optimization methods. The main results are illustrated using different numerical examples.

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