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Hauptverfasser: Peng, Jingruo, Zhu, Shuze
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2601.21881
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author Peng, Jingruo
Zhu, Shuze
author_facet Peng, Jingruo
Zhu, Shuze
contents Humans can infer accurate mechanical outcomes from only a few observations, a capability known as mechanics intuition. The mechanisms behind such data-efficient learning remain unclear. Here, we propose a reinforcement learning framework in which an agent encodes continuous physical observation parameters into its state and is trained via episodic switching across closely related observations. With merely two or three observations, the agent acquires robust mechanics intuition that generalizes accurately over wide parameter ranges, substantially beyond the training data, as demonstrated on the brachistochrone and a large-deformation elastic plate. We explain this generalization through a unified theoretical view: it emerges when the learned value function enforces Bellman consistency across neighboring task parameters, rendering the Bellman residual stationary with respect to physical variations. This induces a smooth policy that captures a low-dimensional solution manifold underlying the continuum of tasks. Our work establishes episodic switching as a principled route to artificial mechanics intuition and offers a theoretical link to similar generalization abilities in biological learners.
format Preprint
id arxiv_https___arxiv_org_abs_2601_21881
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Acquiring Human-Like Mechanics Intuition from Scarce Observations via Deep Reinforcement Learning
Peng, Jingruo
Zhu, Shuze
Computational Physics
Humans can infer accurate mechanical outcomes from only a few observations, a capability known as mechanics intuition. The mechanisms behind such data-efficient learning remain unclear. Here, we propose a reinforcement learning framework in which an agent encodes continuous physical observation parameters into its state and is trained via episodic switching across closely related observations. With merely two or three observations, the agent acquires robust mechanics intuition that generalizes accurately over wide parameter ranges, substantially beyond the training data, as demonstrated on the brachistochrone and a large-deformation elastic plate. We explain this generalization through a unified theoretical view: it emerges when the learned value function enforces Bellman consistency across neighboring task parameters, rendering the Bellman residual stationary with respect to physical variations. This induces a smooth policy that captures a low-dimensional solution manifold underlying the continuum of tasks. Our work establishes episodic switching as a principled route to artificial mechanics intuition and offers a theoretical link to similar generalization abilities in biological learners.
title Acquiring Human-Like Mechanics Intuition from Scarce Observations via Deep Reinforcement Learning
topic Computational Physics
url https://arxiv.org/abs/2601.21881