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Bibliographic Details
Main Authors: Sidiropoulos, Antonis, Doulgeri, Zoe
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2303.03204
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author Sidiropoulos, Antonis
Doulgeri, Zoe
author_facet Sidiropoulos, Antonis
Doulgeri, Zoe
contents DMP have been extensively applied in various robotic tasks thanks to their generalization and robustness properties. However, the successful execution of a given task may necessitate the use of different motion patterns that take into account not only the initial and target position but also features relating to the overall structure and layout of the scene. To make DMP applicable to a wider range of tasks and further automate their use, we design a framework combining deep residual networks with DMP, that can encapsulate different motion patterns of a planar task, provided through human demonstrations on the RGB image plane. We can then automatically infer from new raw RGB visual input the appropriate DMP parameters, i.e. the weights that determine the motion pattern and the initial/target positions. We compare our method against another SoA method for inferring DMP from images and carry out experimental validations in two different planar tasks.
format Preprint
id arxiv_https___arxiv_org_abs_2303_03204
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle From RGB images to Dynamic Movement Primitives for planar tasks
Sidiropoulos, Antonis
Doulgeri, Zoe
Robotics
DMP have been extensively applied in various robotic tasks thanks to their generalization and robustness properties. However, the successful execution of a given task may necessitate the use of different motion patterns that take into account not only the initial and target position but also features relating to the overall structure and layout of the scene. To make DMP applicable to a wider range of tasks and further automate their use, we design a framework combining deep residual networks with DMP, that can encapsulate different motion patterns of a planar task, provided through human demonstrations on the RGB image plane. We can then automatically infer from new raw RGB visual input the appropriate DMP parameters, i.e. the weights that determine the motion pattern and the initial/target positions. We compare our method against another SoA method for inferring DMP from images and carry out experimental validations in two different planar tasks.
title From RGB images to Dynamic Movement Primitives for planar tasks
topic Robotics
url https://arxiv.org/abs/2303.03204