Differentiable Likelihoods for Fast Inversion of ’Likelihood-Free’ Dynamical Systems
Abstract
Likelihood-free (a.k.a. simulation-based) inference problems are inverse problems with expensive, or intractable, forward models. ODE inverse problems are commonly treated as likelihood-free, as their forward map has to be numerically approximated by an ODE solver. This, however, is not a fundamental constraint but just a lack of functionality in classic ODE solvers, which do not return a likelihood but a point estimate. To address this shortcoming, we employ Gaussian ODE filtering (a probabilistic numerical method for ODEs) to construct a local Gaussian approximation to the likelihood. This approximation yields tractable estimators for the gradient and Hessian of the (log-)likelihood. Insertion of these estimators into existing gradient-based optimization and sampling methods engenders new solvers for ODE inverse problems. We demonstrate that these methods outperform standard likelihood-free approaches on three benchmark-systems.
Cite
Text
Kersting et al. "Differentiable Likelihoods for Fast Inversion of ’Likelihood-Free’ Dynamical Systems." International Conference on Machine Learning, 2020.Markdown
[Kersting et al. "Differentiable Likelihoods for Fast Inversion of ’Likelihood-Free’ Dynamical Systems." International Conference on Machine Learning, 2020.](https://mlanthology.org/icml/2020/kersting2020icml-differentiable/)BibTeX
@inproceedings{kersting2020icml-differentiable,
title = {{Differentiable Likelihoods for Fast Inversion of ’Likelihood-Free’ Dynamical Systems}},
author = {Kersting, Hans and Krämer, Nicholas and Schiegg, Martin and Daniel, Christian and Tiemann, Michael and Hennig, Philipp},
booktitle = {International Conference on Machine Learning},
year = {2020},
pages = {5198-5208},
volume = {119},
url = {https://mlanthology.org/icml/2020/kersting2020icml-differentiable/}
}