The self-learning Monte Carlo (SLMC) method is a general algorithm to speedup MC simulations. Its efficiency has been demonstrated in various systems by introducing an effective model to propose global moves in the configuration space. In this paper, we show that deep neural networks can be naturally incorporated into SLMC, and without any prior knowledge can learn the original model accurately and efficiently. Demonstrated in quantum impurity models, we reduce the complexity for a local update from O(β²) in Hirsch-Fye algorithm to O(βlnβ), which is a significant speedup especially for systems at low temperatures.United States. Department of Energy. Office of Basic Energy Sciences (Award DE-SC0010526
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Quantum Monte-Carlo simulations of hybrid quantum-classical models such as the double exchange Hamil...
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Deep neural networks have been very successful as highly accurate wave function Ansätze for variatio...
We examine the zero-temperature Metropolis Monte Carlo (MC) algorithm as a tool for training a neura...
Deep Learning architectures give brilliant results in a large variety of fields, but a comprehensive...
The thesis research involves the application of machine learning (ML) to various parts of a Monte Ca...
We design generative neural networks that generate Monte Carlo configurations with complete absence ...
Monte Carlo simulation is an unbiased numerical tool for studying classical and quantum many-body sy...
Monte Carlo (MC) simulations are essential computational approaches with widespread use throughout a...
The self-learning Monte Carlo method is a powerful general-purpose numerical method recently introdu...
The projective quantum Monte Carlo (PQMC) algorithms are among the most powerful computational techn...
Machine learning and deep learning have revolutionized computational physics, particularly the simul...
Supervised machine learning is emerging as a powerful computational tool to predict the properties o...
The recently introduced self-learning Monte Carlo method is a general-purpose numerical method that ...
Quantum Monte-Carlo simulations of hybrid quantum-classical models such as the double exchange Hamil...
We investigate the use of variational wave functions that mimic stochastic recurrent neural networks...
Deep neural networks have been very successful as highly accurate wave function Ansätze for variatio...
We examine the zero-temperature Metropolis Monte Carlo (MC) algorithm as a tool for training a neura...
Deep Learning architectures give brilliant results in a large variety of fields, but a comprehensive...
The thesis research involves the application of machine learning (ML) to various parts of a Monte Ca...