Physics-Informed Neural Networks to Model and Control Robots: A Theoretical and Experimental Investigation

Jingyue Liu; Pablo Borja; Cosimo Della Santina

doi:10.1002/aisy.202300385

Physics-Informed Neural Networks to Model and Control Robots: A Theoretical and Experimental Investigation

Jingyue Liu
, Pablo Borja
, Cosimo Della Santina

Delft University of Technology
University of Plymouth
Deutsches Zentrum für Luft- und Raumfahrt (DLR)

Research output: Contribution to journal › Article › peer-review

53 Scopus citations

Abstract

This work concerns the application of physics-informed neural networks to the modeling and control of complex robotic systems. Achieving this goal requires extending physics-informed neural networks to handle nonconservative effects. These learned models are proposed to combine with model-based controllers originally developed with first-principle models in mind. By combining standard and new techniques, precise control performance can be achieved while proving theoretical stability bounds. These validations include real-world experiments of motion prediction with a soft robot and trajectory tracking with a Franka Emika Panda manipulator.

Original language	English
Article number	2300385
Journal	Advanced Intelligent Systems
Volume	6
Issue number	5
DOIs	https://doi.org/10.1002/aisy.202300385
State	Published - May 2024
Externally published	Yes

Keywords

Euler–Lagrange equations
Hamiltonian neural networks
Lagrangian neural networks
dissipation
model-based control
physics-informed neural networks
port-Hamiltonian systems

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10.1002/aisy.202300385

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title = "Physics-Informed Neural Networks to Model and Control Robots: A Theoretical and Experimental Investigation",

abstract = "This work concerns the application of physics-informed neural networks to the modeling and control of complex robotic systems. Achieving this goal requires extending physics-informed neural networks to handle nonconservative effects. These learned models are proposed to combine with model-based controllers originally developed with first-principle models in mind. By combining standard and new techniques, precise control performance can be achieved while proving theoretical stability bounds. These validations include real-world experiments of motion prediction with a soft robot and trajectory tracking with a Franka Emika Panda manipulator.",

keywords = "Euler–Lagrange equations, Hamiltonian neural networks, Lagrangian neural networks, dissipation, model-based control, physics-informed neural networks, port-Hamiltonian systems",

author = "Jingyue Liu and Pablo Borja and \{Della Santina\}, Cosimo",

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AU - Della Santina, Cosimo

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N2 - This work concerns the application of physics-informed neural networks to the modeling and control of complex robotic systems. Achieving this goal requires extending physics-informed neural networks to handle nonconservative effects. These learned models are proposed to combine with model-based controllers originally developed with first-principle models in mind. By combining standard and new techniques, precise control performance can be achieved while proving theoretical stability bounds. These validations include real-world experiments of motion prediction with a soft robot and trajectory tracking with a Franka Emika Panda manipulator.

AB - This work concerns the application of physics-informed neural networks to the modeling and control of complex robotic systems. Achieving this goal requires extending physics-informed neural networks to handle nonconservative effects. These learned models are proposed to combine with model-based controllers originally developed with first-principle models in mind. By combining standard and new techniques, precise control performance can be achieved while proving theoretical stability bounds. These validations include real-world experiments of motion prediction with a soft robot and trajectory tracking with a Franka Emika Panda manipulator.

KW - Euler–Lagrange equations

KW - Hamiltonian neural networks

KW - Lagrangian neural networks

KW - dissipation

KW - model-based control

KW - physics-informed neural networks

KW - port-Hamiltonian systems

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JO - Advanced Intelligent Systems

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M1 - 2300385

ER -

Physics-Informed Neural Networks to Model and Control Robots: A Theoretical and Experimental Investigation

Abstract

Keywords

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