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Autori principali: Larby, Daniel, Forni, Fulvio
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2411.06627
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author Larby, Daniel
Forni, Fulvio
author_facet Larby, Daniel
Forni, Fulvio
contents Passivity-based control is a cornerstone of control theory and an established design approach in robotics. Its strength is based on the passivity theorem, which provides a powerful interconnection framework for robotics. However, the design of passivity-based controllers and their optimal tuning remain challenging. We propose here an intuitive design approach for fully actuated robots, where the control action is determined by a `virtual-mechanism' as in classical virtual model control. The result is a robot whose controlled behavior can be understood in terms of physics. We achieve optimal tuning by applying algorithmic differentiation to ODE simulations of the rigid body dynamics. Overall, this leads to a flexible design and optimization approach: stability is proven by passivity of the virtual mechanism, while performance is obtained by optimization using algorithmic differentiation.
format Preprint
id arxiv_https___arxiv_org_abs_2411_06627
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimal Virtual Model Control for Robotics: Design and Tuning of Passivity-Based Controllers
Larby, Daniel
Forni, Fulvio
Robotics
Passivity-based control is a cornerstone of control theory and an established design approach in robotics. Its strength is based on the passivity theorem, which provides a powerful interconnection framework for robotics. However, the design of passivity-based controllers and their optimal tuning remain challenging. We propose here an intuitive design approach for fully actuated robots, where the control action is determined by a `virtual-mechanism' as in classical virtual model control. The result is a robot whose controlled behavior can be understood in terms of physics. We achieve optimal tuning by applying algorithmic differentiation to ODE simulations of the rigid body dynamics. Overall, this leads to a flexible design and optimization approach: stability is proven by passivity of the virtual mechanism, while performance is obtained by optimization using algorithmic differentiation.
title Optimal Virtual Model Control for Robotics: Design and Tuning of Passivity-Based Controllers
topic Robotics
url https://arxiv.org/abs/2411.06627