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Bibliographic Details
Main Authors: Schempp, Constantin, Friedrich, Christian
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.07017
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author Schempp, Constantin
Friedrich, Christian
author_facet Schempp, Constantin
Friedrich, Christian
contents We propose a visual servoing method consisting of a detection network and a velocity trajectory planner. First, the detection network estimates the objects position and orientation in the image space. Furthermore, these are normalized and filtered. The direction and orientation is then the input to the trajectory planner, which considers the kinematic constrains of the used robotic system. This allows safe and stable control, since the kinematic boundary values are taken into account in planning. Also, by having direction estimation and velocity planner separated, the learning part of the method does not directly influence the control value. This also enables the transfer of the method to different robotic systems without retraining, therefore being robot agnostic. We evaluate our method on different visual servoing tasks with and without clutter on two different robotic systems. Our method achieved mean absolute position errors of <0.5 mm and orientation errors of <1°. Additionally, we transferred the method to a new system which differs in robot and camera, emphasizing robot agnostic capability of our method.
format Preprint
id arxiv_https___arxiv_org_abs_2405_07017
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Robot Agnostic Visual Servoing considering kinematic constraints enabled by a decoupled network trajectory planner structure
Schempp, Constantin
Friedrich, Christian
Robotics
We propose a visual servoing method consisting of a detection network and a velocity trajectory planner. First, the detection network estimates the objects position and orientation in the image space. Furthermore, these are normalized and filtered. The direction and orientation is then the input to the trajectory planner, which considers the kinematic constrains of the used robotic system. This allows safe and stable control, since the kinematic boundary values are taken into account in planning. Also, by having direction estimation and velocity planner separated, the learning part of the method does not directly influence the control value. This also enables the transfer of the method to different robotic systems without retraining, therefore being robot agnostic. We evaluate our method on different visual servoing tasks with and without clutter on two different robotic systems. Our method achieved mean absolute position errors of <0.5 mm and orientation errors of <1°. Additionally, we transferred the method to a new system which differs in robot and camera, emphasizing robot agnostic capability of our method.
title Robot Agnostic Visual Servoing considering kinematic constraints enabled by a decoupled network trajectory planner structure
topic Robotics
url https://arxiv.org/abs/2405.07017