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Autori principali: Lyu, Jiangran, Li, Ziming, Shi, Xuesong, Xu, Chaoyi, Wang, Yizhou, Wang, He
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2503.16806
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author Lyu, Jiangran
Li, Ziming
Shi, Xuesong
Xu, Chaoyi
Wang, Yizhou
Wang, He
author_facet Lyu, Jiangran
Li, Ziming
Shi, Xuesong
Xu, Chaoyi
Wang, Yizhou
Wang, He
contents Nonprehensile manipulation is crucial for handling objects that are too thin, large, or otherwise ungraspable in unstructured environments. While conventional planning-based approaches struggle with complex contact modeling, learning-based methods have recently emerged as a promising alternative. However, existing learning-based approaches face two major limitations: they heavily rely on multi-view cameras and precise pose tracking, and they fail to generalize across varying physical conditions, such as changes in object mass and table friction. To address these challenges, we propose the Dynamics-Adaptive World Action Model (DyWA), a novel framework that enhances action learning by jointly predicting future states while adapting to dynamics variations based on historical trajectories. By unifying the modeling of geometry, state, physics, and robot actions, DyWA enables more robust policy learning under partial observability. Compared to baselines, our method improves the success rate by 31.5% using only single-view point cloud observations in the simulation. Furthermore, DyWA achieves an average success rate of 68% in real-world experiments, demonstrating its ability to generalize across diverse object geometries, adapt to varying table friction, and robustness in challenging scenarios such as half-filled water bottles and slippery surfaces.
format Preprint
id arxiv_https___arxiv_org_abs_2503_16806
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle DyWA: Dynamics-adaptive World Action Model for Generalizable Non-prehensile Manipulation
Lyu, Jiangran
Li, Ziming
Shi, Xuesong
Xu, Chaoyi
Wang, Yizhou
Wang, He
Robotics
Artificial Intelligence
Nonprehensile manipulation is crucial for handling objects that are too thin, large, or otherwise ungraspable in unstructured environments. While conventional planning-based approaches struggle with complex contact modeling, learning-based methods have recently emerged as a promising alternative. However, existing learning-based approaches face two major limitations: they heavily rely on multi-view cameras and precise pose tracking, and they fail to generalize across varying physical conditions, such as changes in object mass and table friction. To address these challenges, we propose the Dynamics-Adaptive World Action Model (DyWA), a novel framework that enhances action learning by jointly predicting future states while adapting to dynamics variations based on historical trajectories. By unifying the modeling of geometry, state, physics, and robot actions, DyWA enables more robust policy learning under partial observability. Compared to baselines, our method improves the success rate by 31.5% using only single-view point cloud observations in the simulation. Furthermore, DyWA achieves an average success rate of 68% in real-world experiments, demonstrating its ability to generalize across diverse object geometries, adapt to varying table friction, and robustness in challenging scenarios such as half-filled water bottles and slippery surfaces.
title DyWA: Dynamics-adaptive World Action Model for Generalizable Non-prehensile Manipulation
topic Robotics
Artificial Intelligence
url https://arxiv.org/abs/2503.16806