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Autori principali: Gautier, Nicolas, Guillermit, Yves, Porez, Mathieu, Lemoine, David, Chablat, Damien
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.15290
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author Gautier, Nicolas
Guillermit, Yves
Porez, Mathieu
Lemoine, David
Chablat, Damien
author_facet Gautier, Nicolas
Guillermit, Yves
Porez, Mathieu
Lemoine, David
Chablat, Damien
contents This study presents a methodology for determining the optimal base placement of a Fanuc CRX10iA/L collaborative robot for a desired trajectory corresponding to an industrial task. The proposed method uses a particle swarm optimization algorithm that explores the search space to find positions for performing the trajectory. An $α$-shape algorithm is then used to draw the borders of the feasibility areas, and the largest circle inscribed is calculated from the Voronoi diagrams. The aim of this approach is to provide a robustness criterion in the context of robot placement inaccuracies that may be encountered, for example, if the robot is placed on a mobile base when the system is deployed by an operator. The approach developed uses an inverse kinematics model to evaluate all initial configurations, then moves the robot end-effector along the reference trajectory using the Jacobian matrix and assigns a score to the attempt. For the Fanuc CRX10iA/L robot, there can be up to 16 solutions to the inverse kinematics model. The calculation of these solutions is not trivial and requires a specific study that planning tools such as MoveIt cannot fully take into account. Additionally, the optimization process must consider constraints such as joint limits, singularities, and workspace limitations to ensure feasible and efficient trajectory execution.
format Preprint
id arxiv_https___arxiv_org_abs_2511_15290
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimizing Robot Positioning Against Placement Inaccuracies: A Study on the Fanuc CRX10iA/L
Gautier, Nicolas
Guillermit, Yves
Porez, Mathieu
Lemoine, David
Chablat, Damien
Robotics
This study presents a methodology for determining the optimal base placement of a Fanuc CRX10iA/L collaborative robot for a desired trajectory corresponding to an industrial task. The proposed method uses a particle swarm optimization algorithm that explores the search space to find positions for performing the trajectory. An $α$-shape algorithm is then used to draw the borders of the feasibility areas, and the largest circle inscribed is calculated from the Voronoi diagrams. The aim of this approach is to provide a robustness criterion in the context of robot placement inaccuracies that may be encountered, for example, if the robot is placed on a mobile base when the system is deployed by an operator. The approach developed uses an inverse kinematics model to evaluate all initial configurations, then moves the robot end-effector along the reference trajectory using the Jacobian matrix and assigns a score to the attempt. For the Fanuc CRX10iA/L robot, there can be up to 16 solutions to the inverse kinematics model. The calculation of these solutions is not trivial and requires a specific study that planning tools such as MoveIt cannot fully take into account. Additionally, the optimization process must consider constraints such as joint limits, singularities, and workspace limitations to ensure feasible and efficient trajectory execution.
title Optimizing Robot Positioning Against Placement Inaccuracies: A Study on the Fanuc CRX10iA/L
topic Robotics
url https://arxiv.org/abs/2511.15290