Generative models for sampling of lattice field theories

We explore a self-learning Markov chain Monte Carlo method based on the Adversarial Non-linear Independent Components Estimation Monte Carlo, which utilizes generative models and artificial neural networks. We apply this method to the scalar \(\varphi^4\) lattice field theory in the weak-coupling re...

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Bibliographic Details
Published inarXiv.org
Main Authors Medvidovic, Matija, Carrasquilla, Juan, Hayward, Lauren E, Kulchytskyy, Bohdan
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 05.01.2021
Subjects
Artificial neural networks
Field theory
Learning
Markov chains
Monte Carlo simulation
Performance evaluation
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Summary:We explore a self-learning Markov chain Monte Carlo method based on the Adversarial Non-linear Independent Components Estimation Monte Carlo, which utilizes generative models and artificial neural networks. We apply this method to the scalar \(\varphi^4\) lattice field theory in the weak-coupling regime and, in doing so, greatly increase the system sizes explored to date with this self-learning technique. Our approach does not rely on a pre-existing training set of samples, as the agent systematically improves its performance by bootstrapping samples collected by the model itself. We evaluate the performance of the trained model by examining its mixing time and study the ergodicity of generated samples. When compared to methods such as Hamiltonian Monte Carlo, this approach provides unique advantages such as the speed of inference and a compressed representation of Monte Carlo proposals for potential use in downstream tasks.
ISSN:2331-8422