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

Liu, J; Borja, P; Della Santina, C

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Date

2024

Author

Liu, J

Borja, P

Della Santina, C

Subject

dissipation

Euler-Lagrange equations

Hamiltonian neural networks

Lagrangian neural networks

model-based control

physics-informed neural networks

port-Hamiltonian systems

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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.

Publisher

Wiley

Journal

Advanced Intelligent Systems

Publisher URL

http://dx.doi.org/10.1002/aisy.202300385

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