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Neural Monte Carlo renormalization group

Jui-Hui Chung, Ying-Jer Kao

2021Physical Review Research15 citationsDOIOpen Access PDF

Abstract

The key idea behind the renormalization group (RG) transformation is that properties of physical systems with very different microscopic makeups can be characterized by a few universal parameters. However, finding a systematic way to construct RG transformation for particular systems remains difficult due to the many possible choices of the weight factors in the RG procedure. Here we show, by identifying the conditional distribution in the restricted Boltzmann machine and the weight factor distribution in the RG procedure, that a valid real-space RG transformation can be learned without prior knowledge of the physical system. This neural Monte Carlo RG algorithm allows for direct computation of the RG flow and critical exponents. Our results establish a solid connection between the RG transformation in physics and the deep architecture in machine learning, paving the way for further interdisciplinary research.

Topics & Concepts

Statistical physicsMonte Carlo methodTransformation (genetics)Renormalization groupComputationConnection (principal bundle)Artificial neural networkConstruct (python library)Distribution (mathematics)Physical systemComputer scienceMathematicsPhysicsGroup (periodic table)RenormalizationKey (lock)AlgorithmFlow (mathematics)Complex systemStatistical mechanicsMonte Carlo molecular modelingMonte Carlo method in statistical physicsBoltzmann constantTerm (time)Applied mathematicsCurrent (fluid)Boltzmann distributionProbability distributionMonte Carlo algorithmQuantum many-body systemsMachine Learning in Materials ScienceModel Reduction and Neural Networks