Generalizing Hamiltonian Monte Carlo with Neural Networks
Abstract
We present a general-purpose method to train Markov chain Monte Carlo kernels, parameterized by deep neural networks, that converge and mix quickly to their target distribution. Our method generalizes Hamiltonian Monte Carlo and is trained to maximize expected squared jumped distance, a proxy for mixing speed. We demonstrate large empirical gains on a collection of simple but challenging distributions, for instance achieving a 106x improvement in effective sample size in one case, and mixing when standard HMC makes no measurable progress in a second. Finally, we show quantitative and qualitative gains on a real-world task: latent-variable generative modeling. Python source code will be open-sourced with the camera-ready paper.
Cite
Text
Levy et al. "Generalizing Hamiltonian Monte Carlo with Neural Networks." International Conference on Learning Representations, 2018.Markdown
[Levy et al. "Generalizing Hamiltonian Monte Carlo with Neural Networks." International Conference on Learning Representations, 2018.](https://mlanthology.org/iclr/2018/levy2018iclr-generalizing/)BibTeX
@inproceedings{levy2018iclr-generalizing,
title = {{Generalizing Hamiltonian Monte Carlo with Neural Networks}},
author = {Levy, Daniel and Hoffman, Matt D. and Sohl-Dickstein, Jascha},
booktitle = {International Conference on Learning Representations},
year = {2018},
url = {https://mlanthology.org/iclr/2018/levy2018iclr-generalizing/}
}