Paul Werner Lödige, Maximilian Xiling Li, Rudolf Lioutikov
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引用次数: 0
Abstract
Movement Primitives (MPs) are a well-established method for representing and
generating modular robot trajectories. This work presents FA-ProDMP, a new
approach which introduces force awareness to Probabilistic Dynamic Movement
Primitives (ProDMP). FA-ProDMP adapts the trajectory during runtime to account
for measured and desired forces. It offers smooth trajectories and captures
position and force correlations over multiple trajectories, e.g. a set of human
demonstrations. FA-ProDMP supports multiple axes of force and is thus agnostic
to cartesian or joint space control. This makes FA-ProDMP a valuable tool for
learning contact rich manipulation tasks such as polishing, cutting or
industrial assembly from demonstration. In order to reliably evaluate
FA-ProDMP, this work additionally introduces a modular, 3D printed task suite
called POEMPEL, inspired by the popular Lego Technic pins. POEMPEL mimics
industrial peg-in-hole assembly tasks with force requirements. It offers
multiple parameters of adjustment, such as position, orientation and plug
stiffness level, thus varying the direction and amount of required forces. Our
experiments show that FA-ProDMP outperforms other MP formulations on the
POEMPEL setup and a electrical power plug insertion task, due to its replanning
capabilities based on the measured forces. These findings highlight how
FA-ProDMP enhances the performance of robotic systems in contact-rich
manipulation tasks.
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