Experimental Study of Neural ODE Training with Adaptive Solver for Dynamical Systems Modeling
Abstract
Neural Ordinary Differential Equations (ODEs) was recently introduced as a new family of neural network models, which relies on black-box ODE solvers for inference and training. Some ODE solvers called adaptive can adapt their evaluation strategy depending on the complexity of the problem at hand, opening great perspectives in machine learning. However, this paper describes a simple set of experiments to show why adaptive solvers cannot be seamlessly leveraged as a black-box for dynamical systems modelling. By taking the Lorenz'63 system as a showcase, we show that a naive application of the Fehlberg's method does not yield the expected results. Moreover, a simple workaround is proposed that assumes a tighter interaction between the solver and the training strategy.
Cite
Text
Allauzen et al. "Experimental Study of Neural ODE Training with Adaptive Solver for Dynamical Systems Modeling." NeurIPS 2022 Workshops: DLDE, 2022.Markdown
[Allauzen et al. "Experimental Study of Neural ODE Training with Adaptive Solver for Dynamical Systems Modeling." NeurIPS 2022 Workshops: DLDE, 2022.](https://mlanthology.org/neuripsw/2022/allauzen2022neuripsw-experimental/)BibTeX
@inproceedings{allauzen2022neuripsw-experimental,
title = {{Experimental Study of Neural ODE Training with Adaptive Solver for Dynamical Systems Modeling}},
author = {Allauzen, Alexandre and Dardis, Thiago Petrilli Maffei and Plath, Hannah},
booktitle = {NeurIPS 2022 Workshops: DLDE},
year = {2022},
url = {https://mlanthology.org/neuripsw/2022/allauzen2022neuripsw-experimental/}
}