Neural Lumped Parameter Differential Equations with Application in Friction-Stir Processing
Abstract
Lumped parameter methods aim to simplify the evolution of spatially-extended or continuous physical systems to that of a "lumped" element representative of the physical scales of the modeled system. For systems where the definition of a lumped element or its associated physics may be unknown, modeling tasks may be restricted to full-fidelity simulations of the physics of a system. In this work, we consider data-driven modeling tasks with limited point-wise measurements of otherwise continuous systems. We build upon the notion of the Universal Differential Equation (UDE) to construct data-driven models for reducing dynamics to that of a lumped parameter and inferring its properties. The flexibility of UDEs allow for composing various known physical priors suitable for application-specific modeling tasks, including lumped parameter methods. The motivating example for this work is the plunge and dwell stages for friction-stir welding; specifically, (i) mapping power input into the tool to a point-measurement of temperature and (ii) using this learned mapping for process control.
Cite
@article{arxiv.2304.09047,
title = {Neural Lumped Parameter Differential Equations with Application in Friction-Stir Processing},
author = {James Koch and WoongJo Choi and Ethan King and David Garcia and Hrishikesh Das and Tianhao Wang and Ken Ross and Keerti Kappagantula},
journal= {arXiv preprint arXiv:2304.09047},
year = {2023}
}