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Main Authors: Gimenez, Andreu Matoses, Wilde, Nils, Pek, Chris, Alonso-Mora, Javier
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.11571
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author Gimenez, Andreu Matoses
Wilde, Nils
Pek, Chris
Alonso-Mora, Javier
author_facet Gimenez, Andreu Matoses
Wilde, Nils
Pek, Chris
Alonso-Mora, Javier
contents Autonomously performing tasks often requires robots to plan high-level discrete actions and continuous low-level motions to realize them. Previous TAMP algorithms have focused mainly on computational performance, completeness, or optimality by making the problem tractable through simplifications and abstractions. However, this comes at the cost of the resulting plans potentially failing to account for the dynamics or complex contacts necessary to reliably perform the task when object manipulation is required. Additionally, approaches that ignore effects of the low-level controllers may not obtain optimal or feasible plan realizations for the real system. We investigate the use of a GPU-parallelized physics simulator to compute realizations of plans with motion controllers, explicitly accounting for dynamics, and considering contacts with the environment. Using cross-entropy optimization, we sample the parameters of the controllers, or actions, to obtain low-cost solutions. Since our approach uses the same controllers as the real system, the robot can directly execute the computed plans. We demonstrate our approach for a set of tasks where the robot is able to exploit the environment's geometry to move an object. Website and code: https://andreumatoses.github.io/research/parallel-realization
format Preprint
id arxiv_https___arxiv_org_abs_2512_11571
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Cross-Entropy Optimization of Physically Grounded Task and Motion Plans
Gimenez, Andreu Matoses
Wilde, Nils
Pek, Chris
Alonso-Mora, Javier
Robotics
Autonomously performing tasks often requires robots to plan high-level discrete actions and continuous low-level motions to realize them. Previous TAMP algorithms have focused mainly on computational performance, completeness, or optimality by making the problem tractable through simplifications and abstractions. However, this comes at the cost of the resulting plans potentially failing to account for the dynamics or complex contacts necessary to reliably perform the task when object manipulation is required. Additionally, approaches that ignore effects of the low-level controllers may not obtain optimal or feasible plan realizations for the real system. We investigate the use of a GPU-parallelized physics simulator to compute realizations of plans with motion controllers, explicitly accounting for dynamics, and considering contacts with the environment. Using cross-entropy optimization, we sample the parameters of the controllers, or actions, to obtain low-cost solutions. Since our approach uses the same controllers as the real system, the robot can directly execute the computed plans. We demonstrate our approach for a set of tasks where the robot is able to exploit the environment's geometry to move an object. Website and code: https://andreumatoses.github.io/research/parallel-realization
title Cross-Entropy Optimization of Physically Grounded Task and Motion Plans
topic Robotics
url https://arxiv.org/abs/2512.11571