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Auteurs principaux: Smith, J. Darby, Lehoucq, Rich, Franke, Brian
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2407.02295
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author Smith, J. Darby
Lehoucq, Rich
Franke, Brian
author_facet Smith, J. Darby
Lehoucq, Rich
Franke, Brian
contents Traditional Monte Carlo methods for particle transport utilize source iteration to express the solution, the flux density, of the transport equation as a Neumann series. Our contribution is to show that the particle paths simulated within source iteration are associated with the adjoint flux density and the adjoint particle paths are associated with the flux density. We make our assertion rigorous through the use of stochastic calculus by representing the particle path used in source iteration as a solution to a stochastic differential equation (SDE). The solution to the adjoint Boltzmann equation is then expressed in terms of the same SDE and the solution to the Boltzmann equation is expressed in terms of the SDE associated with the adjoint particle process. An important consequence is that the particle paths used within source iteration simultaneously provide Monte Carlo approximations of the flux density and adjoint flux density. Monte Carlo simulations are presented to support the simultaneous use of the particle paths.
format Preprint
id arxiv_https___arxiv_org_abs_2407_02295
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Stochastic Calculus Approach to Boltzmann Transport
Smith, J. Darby
Lehoucq, Rich
Franke, Brian
Probability
Mathematical Physics
Traditional Monte Carlo methods for particle transport utilize source iteration to express the solution, the flux density, of the transport equation as a Neumann series. Our contribution is to show that the particle paths simulated within source iteration are associated with the adjoint flux density and the adjoint particle paths are associated with the flux density. We make our assertion rigorous through the use of stochastic calculus by representing the particle path used in source iteration as a solution to a stochastic differential equation (SDE). The solution to the adjoint Boltzmann equation is then expressed in terms of the same SDE and the solution to the Boltzmann equation is expressed in terms of the SDE associated with the adjoint particle process. An important consequence is that the particle paths used within source iteration simultaneously provide Monte Carlo approximations of the flux density and adjoint flux density. Monte Carlo simulations are presented to support the simultaneous use of the particle paths.
title A Stochastic Calculus Approach to Boltzmann Transport
topic Probability
Mathematical Physics
url https://arxiv.org/abs/2407.02295