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Auteurs principaux: Petrichenko, Valentyn, Lokstein, Lisa, Thiele, Gregor, Haninger, Kevin
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2411.03194
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author Petrichenko, Valentyn
Lokstein, Lisa
Thiele, Gregor
Haninger, Kevin
author_facet Petrichenko, Valentyn
Lokstein, Lisa
Thiele, Gregor
Haninger, Kevin
contents The energy use of a robot is trajectory-dependent, and thus can be reduced by optimization of the trajectory. Current methods for robot trajectory optimization can reduce energy up to 15\% for fixed start and end points, however their use in industrial robot planning is still restricted due to model complexity and lack of integration with planning tools which address other concerns (e.g. collision avoidance). We propose an approach that uses differentiable inertial and kinematic models from standard open-source tools, integrating with standard ROS planning methods. An inverse dynamics-based energy model is optionally extended with a single-parameter electrical model, simplifying the model identification process. We compare the inertial and electrical models on a collaborative robot, showing that simplified models provide competitive accuracy and are easier to deploy in practice.
format Preprint
id arxiv_https___arxiv_org_abs_2411_03194
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Energy Consumption in Robotics: A Simplified Modeling Approach
Petrichenko, Valentyn
Lokstein, Lisa
Thiele, Gregor
Haninger, Kevin
Robotics
The energy use of a robot is trajectory-dependent, and thus can be reduced by optimization of the trajectory. Current methods for robot trajectory optimization can reduce energy up to 15\% for fixed start and end points, however their use in industrial robot planning is still restricted due to model complexity and lack of integration with planning tools which address other concerns (e.g. collision avoidance). We propose an approach that uses differentiable inertial and kinematic models from standard open-source tools, integrating with standard ROS planning methods. An inverse dynamics-based energy model is optionally extended with a single-parameter electrical model, simplifying the model identification process. We compare the inertial and electrical models on a collaborative robot, showing that simplified models provide competitive accuracy and are easier to deploy in practice.
title Energy Consumption in Robotics: A Simplified Modeling Approach
topic Robotics
url https://arxiv.org/abs/2411.03194