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Autori principali: Wei, Yunyue, Zuo, Chenhui, Sui, Yanan
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2601.19707
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author Wei, Yunyue
Zuo, Chenhui
Sui, Yanan
author_facet Wei, Yunyue
Zuo, Chenhui
Sui, Yanan
contents Controlling high-dimensional systems in biological and robotic applications is challenging due to expansive state-action spaces, where effective exploration is critical. Commonly used exploration strategies in reinforcement learning are largely undirected with sharp degradation as action dimensionality grows. Many existing methods resort to dimensionality reduction, which constrains policy expressiveness and forfeits system flexibility. We introduce Q-guided Flow Exploration (Qflex), a scalable reinforcement learning method that conducts exploration directly in the native high-dimensional action space. During training, Qflex traverses actions from a learnable source distribution along a probability flow induced by the learned value function, aligning exploration with task-relevant gradients rather than isotropic noise. Our proposed method substantially outperforms representative online reinforcement learning baselines across diverse high-dimensional continuous-control benchmarks. Qflex also successfully controls a full-body human musculoskeletal model to perform agile, complex movements, demonstrating superior scalability and sample efficiency in very high-dimensional settings. Our results indicate that value-guided flows offer a principled and practical route to exploration at scale.
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id arxiv_https___arxiv_org_abs_2601_19707
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Scalable Exploration for High-Dimensional Continuous Control via Value-Guided Flow
Wei, Yunyue
Zuo, Chenhui
Sui, Yanan
Machine Learning
Robotics
Controlling high-dimensional systems in biological and robotic applications is challenging due to expansive state-action spaces, where effective exploration is critical. Commonly used exploration strategies in reinforcement learning are largely undirected with sharp degradation as action dimensionality grows. Many existing methods resort to dimensionality reduction, which constrains policy expressiveness and forfeits system flexibility. We introduce Q-guided Flow Exploration (Qflex), a scalable reinforcement learning method that conducts exploration directly in the native high-dimensional action space. During training, Qflex traverses actions from a learnable source distribution along a probability flow induced by the learned value function, aligning exploration with task-relevant gradients rather than isotropic noise. Our proposed method substantially outperforms representative online reinforcement learning baselines across diverse high-dimensional continuous-control benchmarks. Qflex also successfully controls a full-body human musculoskeletal model to perform agile, complex movements, demonstrating superior scalability and sample efficiency in very high-dimensional settings. Our results indicate that value-guided flows offer a principled and practical route to exploration at scale.
title Scalable Exploration for High-Dimensional Continuous Control via Value-Guided Flow
topic Machine Learning
Robotics
url https://arxiv.org/abs/2601.19707