Saved in:
Bibliographic Details
Main Authors: Zhang, Huan, Webber, Robert J., Lindsey, Michael, Berkelbach, Timothy C., Weare, Jonathan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.01905
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916822638395392
author Zhang, Huan
Webber, Robert J.
Lindsey, Michael
Berkelbach, Timothy C.
Weare, Jonathan
author_facet Zhang, Huan
Webber, Robert J.
Lindsey, Michael
Berkelbach, Timothy C.
Weare, Jonathan
contents Neural network parametrizations have increasingly been used to represent the ground and excited states in variational Monte Carlo (VMC) with promising results. However, traditional VMC methods only optimize the wave function in regions of peak probability. The wave function is uncontrolled in the tails of the probability distribution, which can limit the accuracy of the trained wavefunction approximation. To improve the approximation accuracy in the probability tails, this paper interprets VMC as a gradient flow in the space of wave functions, followed by a projection step. From this perspective, arbitrary probability distributions can be used in the projection step, allowing the user to prioritize accuracy in different regions of state space. Motivated by this theoretical perspective, the paper tests a new weighted VMC method on the antiferromagnetic Heisenberg model for a periodic spin chain. Compared to traditional VMC, weighted VMC reduces the error in the ground state energy by a factor of 2 and it reduces the errors in the local energies away from the mode by large factors of $10^2$--$10^4$.
format Preprint
id arxiv_https___arxiv_org_abs_2507_01905
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Improved energies and wave function accuracy with Weighted Variational Monte Carlo
Zhang, Huan
Webber, Robert J.
Lindsey, Michael
Berkelbach, Timothy C.
Weare, Jonathan
Computational Physics
Quantum Physics
Neural network parametrizations have increasingly been used to represent the ground and excited states in variational Monte Carlo (VMC) with promising results. However, traditional VMC methods only optimize the wave function in regions of peak probability. The wave function is uncontrolled in the tails of the probability distribution, which can limit the accuracy of the trained wavefunction approximation. To improve the approximation accuracy in the probability tails, this paper interprets VMC as a gradient flow in the space of wave functions, followed by a projection step. From this perspective, arbitrary probability distributions can be used in the projection step, allowing the user to prioritize accuracy in different regions of state space. Motivated by this theoretical perspective, the paper tests a new weighted VMC method on the antiferromagnetic Heisenberg model for a periodic spin chain. Compared to traditional VMC, weighted VMC reduces the error in the ground state energy by a factor of 2 and it reduces the errors in the local energies away from the mode by large factors of $10^2$--$10^4$.
title Improved energies and wave function accuracy with Weighted Variational Monte Carlo
topic Computational Physics
Quantum Physics
url https://arxiv.org/abs/2507.01905