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Main Authors: Qian, Moxian, Chen, Shiyang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.19575
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author Qian, Moxian
Chen, Shiyang
author_facet Qian, Moxian
Chen, Shiyang
contents We combine reinforcement learning with variational autoregressive networks (VANs) to perform data-free training and sampling for the discrete Ising model and the continuous $ϕ^4$ scalar field theory. We quantify the complexity of the target distribution via the KL divergence between the magnetization distribution and a reference Gaussian distribution, and observe that configurations with smaller KL divergence typically require fewer training steps. Motivated by this observation, we investigate transfer learning and show that fine-tuning models pretrained at a single value of $κ$ can reduce training time compared with training from a Gaussian field. In addition, inspired by single-site and cluster Monte Carlo updates, we introduce single-site and block Metropolis--Hastings (MH) updates on top of VAN proposals. These MH corrections systematically reduce the residual bias of pure VAN sampling in the parameter range we study, while maintaining high sampling efficiency in terms of the effective sample size (ESS). For both the Ising model and the $ϕ^4$ theory, our results agree with standard Monte Carlo benchmarks within errors, and no clear critical slowing down is observed in the explored parameter ranges.
format Preprint
id arxiv_https___arxiv_org_abs_2512_19575
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Variational Autoregressive Networks Applied to $ϕ^4$ Field Theory Systems
Qian, Moxian
Chen, Shiyang
High Energy Physics - Lattice
We combine reinforcement learning with variational autoregressive networks (VANs) to perform data-free training and sampling for the discrete Ising model and the continuous $ϕ^4$ scalar field theory. We quantify the complexity of the target distribution via the KL divergence between the magnetization distribution and a reference Gaussian distribution, and observe that configurations with smaller KL divergence typically require fewer training steps. Motivated by this observation, we investigate transfer learning and show that fine-tuning models pretrained at a single value of $κ$ can reduce training time compared with training from a Gaussian field. In addition, inspired by single-site and cluster Monte Carlo updates, we introduce single-site and block Metropolis--Hastings (MH) updates on top of VAN proposals. These MH corrections systematically reduce the residual bias of pure VAN sampling in the parameter range we study, while maintaining high sampling efficiency in terms of the effective sample size (ESS). For both the Ising model and the $ϕ^4$ theory, our results agree with standard Monte Carlo benchmarks within errors, and no clear critical slowing down is observed in the explored parameter ranges.
title Variational Autoregressive Networks Applied to $ϕ^4$ Field Theory Systems
topic High Energy Physics - Lattice
url https://arxiv.org/abs/2512.19575