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Autori principali: Ke, Shuai, Zhao, Huan, Li, Xiangfei, Wei, Zhiao, Yin, Yecan, Ding, Han
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2504.17216
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author Ke, Shuai
Zhao, Huan
Li, Xiangfei
Wei, Zhiao
Yin, Yecan
Ding, Han
author_facet Ke, Shuai
Zhao, Huan
Li, Xiangfei
Wei, Zhiao
Yin, Yecan
Ding, Han
contents Learning grinding skills from human craftsmen via imitation learning has become a key research topic in robotic machining. Due to their strong generalization and robustness to external disturbances, Dynamical Movement Primitives (DMPs) offer a promising approach for robotic grinding skill learning. However, directly applying DMPs to grinding tasks faces challenges, such as low orientation accuracy, unsynchronized position-orientation-force, and limited generalization for surface trajectories. To address these issues, this paper proposes a robotic grinding skill learning method based on geodesic length DMPs (Geo-DMPs). First, a normalized 2D weighted Gaussian kernel and intrinsic mean clustering algorithm are developed to extract geometric features from multiple demonstrations. Then, an orientation manifold distance metric removes the time dependency in traditional orientation DMPs, enabling accurate orientation learning via Geo-DMPs. A synchronization encoding framework is further proposed to jointly model position, orientation, and force using a geodesic length-based phase function. This framework enables robotic grinding actions to be generated between any two surface points. Experiments on robotic chamfer grinding and free-form surface grinding validate that the proposed method achieves high geometric accuracy and generalization in skill encoding and generation. To our knowledge, this is the first attempt to use DMPs for jointly learning and generating grinding skills in position, orientation, and force on model-free surfaces, offering a novel path for robotic grinding.
format Preprint
id arxiv_https___arxiv_org_abs_2504_17216
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Robotic Grinding Skills Learning Based on Geodesic Length Dynamic Motion Primitives
Ke, Shuai
Zhao, Huan
Li, Xiangfei
Wei, Zhiao
Yin, Yecan
Ding, Han
Robotics
Learning grinding skills from human craftsmen via imitation learning has become a key research topic in robotic machining. Due to their strong generalization and robustness to external disturbances, Dynamical Movement Primitives (DMPs) offer a promising approach for robotic grinding skill learning. However, directly applying DMPs to grinding tasks faces challenges, such as low orientation accuracy, unsynchronized position-orientation-force, and limited generalization for surface trajectories. To address these issues, this paper proposes a robotic grinding skill learning method based on geodesic length DMPs (Geo-DMPs). First, a normalized 2D weighted Gaussian kernel and intrinsic mean clustering algorithm are developed to extract geometric features from multiple demonstrations. Then, an orientation manifold distance metric removes the time dependency in traditional orientation DMPs, enabling accurate orientation learning via Geo-DMPs. A synchronization encoding framework is further proposed to jointly model position, orientation, and force using a geodesic length-based phase function. This framework enables robotic grinding actions to be generated between any two surface points. Experiments on robotic chamfer grinding and free-form surface grinding validate that the proposed method achieves high geometric accuracy and generalization in skill encoding and generation. To our knowledge, this is the first attempt to use DMPs for jointly learning and generating grinding skills in position, orientation, and force on model-free surfaces, offering a novel path for robotic grinding.
title Robotic Grinding Skills Learning Based on Geodesic Length Dynamic Motion Primitives
topic Robotics
url https://arxiv.org/abs/2504.17216