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Main Authors: Leeftink, David, Yıldız, Çağatay, Ridderbusch, Steffen, Hinne, Max, van Gerven, Marcel
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.02543
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author Leeftink, David
Yıldız, Çağatay
Ridderbusch, Steffen
Hinne, Max
van Gerven, Marcel
author_facet Leeftink, David
Yıldız, Çağatay
Ridderbusch, Steffen
Hinne, Max
van Gerven, Marcel
contents Without exact knowledge of the true system dynamics, optimal control of non-linear continuous-time systems requires careful treatment under epistemic uncertainty. In this work, we translate a probabilistic interpretation of the Pontryagin maximum principle to the challenge of optimal control with learned probabilistic dynamics models. Our framework provides a principled treatment of epistemic uncertainty by minimizing the mean Hamiltonian with respect to a posterior distribution over the system dynamics. We propose a multiple shooting numerical method that leverages mean Hamiltonian minimization and is scalable to large-scale probabilistic dynamics models, including ensemble neural ordinary differential equations. Comparisons against other baselines in online and offline model-based reinforcement learning tasks show that our probabilistic Hamiltonian approach leads to reduced trial costs in offline settings and achieves competitive performance in online scenarios. By bridging optimal control and reinforcement learning, our approach offers a principled and practical framework for controlling uncertain systems with learned dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2504_02543
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimal Control of Probabilistic Dynamics Models via Mean Hamiltonian Minimization
Leeftink, David
Yıldız, Çağatay
Ridderbusch, Steffen
Hinne, Max
van Gerven, Marcel
Machine Learning
Without exact knowledge of the true system dynamics, optimal control of non-linear continuous-time systems requires careful treatment under epistemic uncertainty. In this work, we translate a probabilistic interpretation of the Pontryagin maximum principle to the challenge of optimal control with learned probabilistic dynamics models. Our framework provides a principled treatment of epistemic uncertainty by minimizing the mean Hamiltonian with respect to a posterior distribution over the system dynamics. We propose a multiple shooting numerical method that leverages mean Hamiltonian minimization and is scalable to large-scale probabilistic dynamics models, including ensemble neural ordinary differential equations. Comparisons against other baselines in online and offline model-based reinforcement learning tasks show that our probabilistic Hamiltonian approach leads to reduced trial costs in offline settings and achieves competitive performance in online scenarios. By bridging optimal control and reinforcement learning, our approach offers a principled and practical framework for controlling uncertain systems with learned dynamics.
title Optimal Control of Probabilistic Dynamics Models via Mean Hamiltonian Minimization
topic Machine Learning
url https://arxiv.org/abs/2504.02543