Differentiable Cloth Parameter Identification and State Estimation in Manipulation

In the realm of robotic cloth manipulation, accurately estimating the cloth state during or post-execution is imperative. However, the inherent complexities in a cloth's dynamic behavior and its near-infinite degrees of freedom (DoF) pose significant challenges. Traditional methods have been re...

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Veröffentlicht in:	IEEE robotics and automation letters 2024-03, Vol.9 (3), p.2519-2526
Hauptverfasser:	Zheng, Dongzhe, Yao, Siqiong, Xu, Wenqiang, Lu, Cewu
Format:	Artikel
Sprache:	eng
Schlagworte:	Cloth Constitutive models Degrees of freedom Elastoplasticity Parameter identification Physics Pose estimation State estimation
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creator	Zheng, Dongzhe Yao, Siqiong Xu, Wenqiang Lu, Cewu
description	In the realm of robotic cloth manipulation, accurately estimating the cloth state during or post-execution is imperative. However, the inherent complexities in a cloth's dynamic behavior and its near-infinite degrees of freedom (DoF) pose significant challenges. Traditional methods have been restricted to using keypoints or boundaries as cues for cloth state, which do not holistically capture the cloth's structure, especially during intricate tasks like folding. Additionally, the critical influence of cloth physics has often been overlooked in past research. Addressing these concerns, we introduce DiffCP, a novel differentiable pipeline that leverages the Anisotropic Elasto-Plastic (A-EP) constitutive model, tailored for differentiable computation and robotic tasks. DiffCP adopts a “real-to-sim-to-real” methodology. By observing real-world cloth states through an RGB-D camera and projecting this data into a differentiable simulator, the system identifies physics parameters by minimizing the geometric variance between observed and target states. Extensive experiments demonstrate DiffCP's ability and stability to determine physics parameters under varying manipulations, grasping points, and speeds. Additionally, its applications extend to cloth material identification, manipulation trajectory generation, and more notably, enhancing cloth pose estimation accuracy.
doi_str_mv	10.1109/LRA.2024.3357039
format	Article
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subjects	Cloth Constitutive models Degrees of freedom Elastoplasticity Parameter identification Physics Pose estimation State estimation
title	Differentiable Cloth Parameter Identification and State Estimation in Manipulation
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