Learning Deformation Trajectories of Boltzmann Densities
Abstract
We introduce a training objective for continuous normalizing flows that can be used in the absence of samples but in the presence of an energy function. Our method relies on either a prescribed or a learnt interpolation $f_t$ of energy functions between the target energy $f_1$ and the energy function of a generalized Gaussian $f_0(x) = ||x/\sigma||_p^p$. The interpolation of energy functions induces an interpolation of Boltzmann densities $p_t \propto e^{-f_t}$ and we aim to find a time-dependent vector field $V_t$ that transports samples along the family $p_t$ of densities. The condition of transporting samples along the family $p_t$ can be translated to a PDE between $V_t$ and $f_t$ and we optimize $V_t$ and $f_t$ to satisfy this PDE.
Cite
Text
Máté and Fleuret. "Learning Deformation Trajectories of Boltzmann Densities." ICLR 2023 Workshops: Physics4ML, 2023.Markdown
[Máté and Fleuret. "Learning Deformation Trajectories of Boltzmann Densities." ICLR 2023 Workshops: Physics4ML, 2023.](https://mlanthology.org/iclrw/2023/mate2023iclrw-learning/)BibTeX
@inproceedings{mate2023iclrw-learning,
title = {{Learning Deformation Trajectories of Boltzmann Densities}},
author = {Máté, Bálint and Fleuret, François},
booktitle = {ICLR 2023 Workshops: Physics4ML},
year = {2023},
url = {https://mlanthology.org/iclrw/2023/mate2023iclrw-learning/}
}