English

Targeted free energy estimation via learned mappings

Computational Physics 2020-10-28 v2 Chemical Physics Machine Learning

Abstract

Free energy perturbation (FEP) was proposed by Zwanzig more than six decades ago as a method to estimate free energy differences, and has since inspired a huge body of related methods that use it as an integral building block. Being an importance sampling based estimator, however, FEP suffers from a severe limitation: the requirement of sufficient overlap between distributions. One strategy to mitigate this problem, called Targeted Free Energy Perturbation, uses a high-dimensional mapping in configuration space to increase overlap of the underlying distributions. Despite its potential, this method has attracted only limited attention due to the formidable challenge of formulating a tractable mapping. Here, we cast Targeted FEP as a machine learning problem in which the mapping is parameterized as a neural network that is optimized so as to increase overlap. We develop a new model architecture that respects permutational and periodic symmetries often encountered in atomistic simulations and test our method on a fully-periodic solvation system. We demonstrate that our method leads to a substantial variance reduction in free energy estimates when compared against baselines, without requiring any additional data.

Keywords

Cite

@article{arxiv.2002.04913,
  title  = {Targeted free energy estimation via learned mappings},
  author = {Peter Wirnsberger and Andrew J. Ballard and George Papamakarios and Stuart Abercrombie and Sébastien Racanière and Alexander Pritzel and Danilo Jimenez Rezende and Charles Blundell},
  journal= {arXiv preprint arXiv:2002.04913},
  year   = {2020}
}

Comments

Added figure 3, added data augmentation for octahedral symmetries, updated experimental results and revised text (11 pages, 6 figures)

R2 v1 2026-06-23T13:39:25.100Z