English

Neural Dynamical Systems: Balancing Structure and Flexibility in Physical Prediction

Machine Learning 2022-03-16 v2 Machine Learning

Abstract

We introduce Neural Dynamical Systems (NDS), a method of learning dynamical models in various gray-box settings which incorporates prior knowledge in the form of systems of ordinary differential equations. NDS uses neural networks to estimate free parameters of the system, predicts residual terms, and numerically integrates over time to predict future states. A key insight is that many real dynamical systems of interest are hard to model because the dynamics may vary across rollouts. We mitigate this problem by taking a trajectory of prior states as the input to NDS and train it to dynamically estimate system parameters using the preceding trajectory. We find that NDS learns dynamics with higher accuracy and fewer samples than a variety of deep learning methods that do not incorporate the prior knowledge and methods from the system identification literature which do. We demonstrate these advantages first on synthetic dynamical systems and then on real data captured from deuterium shots from a nuclear fusion reactor. Finally, we demonstrate that these benefits can be utilized for control in small-scale experiments.

Keywords

Cite

@article{arxiv.2006.12682,
  title  = {Neural Dynamical Systems: Balancing Structure and Flexibility in Physical Prediction},
  author = {Viraj Mehta and Ian Char and Willie Neiswanger and Youngseog Chung and Andrew Oakleigh Nelson and Mark D Boyer and Egemen Kolemen and Jeff Schneider},
  journal= {arXiv preprint arXiv:2006.12682},
  year   = {2022}
}
R2 v1 2026-06-23T16:32:27.703Z