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Learning to control switching nonlinear systems with Koopman operator regression

Edoardo Caldarelli, Oleksii Kachaiev, Cesare Molinari, Lorenzo Rosasco

Year
2026
Access
Open access

Abstract

In this work, we consider the identification and control of nonlinear systems with finite action spaces. The unknown dynamics are estimated from finite samples with Koopman operator regression in a reproducing kernel Hilbert space, yielding a linear switching predictive model, the switches governed by the value of the control variable. In order to perform control in closed-loop, the learned dynamics are employed in an infinite-horizon optimal control problem with time-varying stage cost, which is solved by means of model predictive control. In a theoretical analysis, we derive learning rates for the Koopman dynamics approximation. We further quantify, under suitable assumptions, the sub-optimality of the model predictive control strategy, both in the case of exact Koopman dynamics, and in the case of learned ones. Numerical simulations on the Duffing oscillator complement our theoretical findings.

Keywords

Koopman operatornonlinear controlmodel predictive controlswitching systemslearning rates

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