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Bibliographic Details
Main Authors: Wüthrich, Joschua, Damle, Romir, Fieni, Giona, Zeilinger, Melanie N., Onder, Christopher H., Carron, Andrea
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.00826
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author Wüthrich, Joschua
Damle, Romir
Fieni, Giona
Zeilinger, Melanie N.
Onder, Christopher H.
Carron, Andrea
author_facet Wüthrich, Joschua
Damle, Romir
Fieni, Giona
Zeilinger, Melanie N.
Onder, Christopher H.
Carron, Andrea
contents We propose a hybrid reinforcement learning (RL) and model predictive control (MPC) framework for mixed-integer optimal control, where discrete variables enter the cost and dynamics but not the constraints. Existing hierarchical approaches use RL only for the discrete action space, leaving continuous optimization to MPC. Unlike these methods, we train the RL agent on the full hybrid action space, ensuring consistency with the cost of the underlying Markov decision process. During deployment, the RL actor is rolled out over the prediction horizon to parametrize an integer-free nonlinear MPC through the discrete action sequence and provide a continuous warm-start. The learned critic serves as a terminal cost to capture long-term performance. We prove recursive feasibility, and validate the framework on a Formula 1 race strategy problem. The hybrid method achieves near-optimal performance relative to an offline mixed-integer nonlinear program benchmark, outperforming a standalone RL agent. Moreover, the hybrid scheme enables adaptation to unseen disturbances through modular MPC extensions at zero retraining cost.
format Preprint
id arxiv_https___arxiv_org_abs_2604_00826
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Bridging RL and MPC for mixed-integer optimal control with application to Formula 1 race strategies
Wüthrich, Joschua
Damle, Romir
Fieni, Giona
Zeilinger, Melanie N.
Onder, Christopher H.
Carron, Andrea
Systems and Control
We propose a hybrid reinforcement learning (RL) and model predictive control (MPC) framework for mixed-integer optimal control, where discrete variables enter the cost and dynamics but not the constraints. Existing hierarchical approaches use RL only for the discrete action space, leaving continuous optimization to MPC. Unlike these methods, we train the RL agent on the full hybrid action space, ensuring consistency with the cost of the underlying Markov decision process. During deployment, the RL actor is rolled out over the prediction horizon to parametrize an integer-free nonlinear MPC through the discrete action sequence and provide a continuous warm-start. The learned critic serves as a terminal cost to capture long-term performance. We prove recursive feasibility, and validate the framework on a Formula 1 race strategy problem. The hybrid method achieves near-optimal performance relative to an offline mixed-integer nonlinear program benchmark, outperforming a standalone RL agent. Moreover, the hybrid scheme enables adaptation to unseen disturbances through modular MPC extensions at zero retraining cost.
title Bridging RL and MPC for mixed-integer optimal control with application to Formula 1 race strategies
topic Systems and Control
url https://arxiv.org/abs/2604.00826