Related papers: Fourier-Flow model generating Feynman paths

Fourier-Flow model generating Feynman paths

URL: http://arxiv.org/abs/2211.03470v1
Date: Mon, 7 Nov 2022 11:31:40 GMT
Title: Fourier-Flow model generating Feynman paths
Authors: Shile Chen, Oleh Savchuk, Shiqi Zheng, Baoyi Chen, Horst Stoecker, Lingxiao Wang and Kai Zhou
Abstract summary: Feynman path integrals generalize the classical action principle to a probabilistic perspective. The underlying difficulty is to tackle the whole path manifold from finite samples. Modern generative models in machine learning can handle learning and representing probability distribution.
Score: 21.67472055005712
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: As an alternative but unified and more fundamental description for quantum physics, Feynman path integrals generalize the classical action principle to a probabilistic perspective, under which the physical observables' estimation translates into a weighted sum over all possible paths. The underlying difficulty is to tackle the whole path manifold from finite samples that can effectively represent the Feynman propagator dictated probability distribution. Modern generative models in machine learning can handle learning and representing probability distribution with high computational efficiency. In this study, we propose a Fourier-flow generative model to simulate the Feynman propagator and generate paths for quantum systems. As demonstration, we validate the path generator on the harmonic and anharmonic oscillators. The latter is a double-well system without analytic solutions. To preserve the periodic condition for the system, the Fourier transformation is introduced into the flow model to approach a Matsubara representation. With this novel development, the ground-state wave function and low-lying energy levels are estimated accurately. Our method offers a new avenue to investigate quantum systems with machine learning assisted Feynman Path integral solving.

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