Learning Constrained Dynamics with Gauss’ Principle Adhering Gaussian Processes

L4DC 2020 pp. 225-234

/l4dc/2020/geist2020l4dc-learning/

Abstract

The identification of the constrained dynamics of mechanical systems is often challenging. Learning methods promise to ease an analytical analysis, but require considerable amounts of data for training. We propose to combine insights from analytical mechanics with Gaussian process regression to improve the model’s data efficiency and constraint integrity. The result is a Gaussian process model that incorporates a priori constraint knowledge such that its predictions adhere Gauss’ principle of least constraint. In return, predictions of the system’s acceleration naturally respect potentially non-ideal (non-)holonomic equality constraints. As corollary results, our model enables to infer the acceleration of the unconstrained system from data of the constrained system and enables knowledge transfer between differing constraint configurations.

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Text

Geist and Trimpe. "Learning Constrained Dynamics  with Gauss’ Principle Adhering Gaussian Processes." Proceedings of the 2nd Conference on Learning for Dynamics and Control, 2020.

Markdown

[Geist and Trimpe. "Learning Constrained Dynamics  with Gauss’ Principle Adhering Gaussian Processes." Proceedings of the 2nd Conference on Learning for Dynamics and Control, 2020.](https://mlanthology.org/l4dc/2020/geist2020l4dc-learning/)

BibTeX

@inproceedings{geist2020l4dc-learning,
  title     = {{Learning Constrained Dynamics  with Gauss’ Principle Adhering Gaussian Processes}},
  author    = {Geist, Andreas and Trimpe, Sebastian},
  booktitle = {Proceedings of the 2nd Conference on Learning for Dynamics and Control},
  year      = {2020},
  pages     = {225-234},
  volume    = {120},
  url       = {https://mlanthology.org/l4dc/2020/geist2020l4dc-learning/}
}