Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations

It was recently shown that radiation, conduction and convection can be combined within a single Monte Carlo algorithm and that such an algorithm immediately benefits from state-of-the-art computer-graphics advances when dealing with complex geometries. The theoretical foundations that make this coup...

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Autores principales: Tregan, Jean Marc, Amestoy, Jean Luc, Bati, Megane, Bezian, Jean-Jacques, Blanco, Stéphane, Brunel, Laurent, Caliot, Cyril, Charon, Julien, Cornet, Jean-Francois, Coustet, Christophe, d’Alençon, Louis, Dauchet, Jeremi, Dutour, Sebastien, Eibner, Simon, El Hafi, Mouna, Eymet, Vincent, Farges, Olivier, Forest, Vincent, Fournier, Richard, Galtier, Mathieu, Gattepaille, Victor, Gautrais, Jacques, He, Zili, Hourdin, Frédéric, Ibarrart, Loris, Joly, Jean-Louis, Lapeyre, Paule, Lavieille, Pascal, Lecureux, Marie-Helene, Lluc, Jacques, Miscevic, Marc, Mourtaday, Nada, Nyffenegger-Péré, Yaniss, Pelissier, Lionel, Penazzi, Lea, Piaud, Benjamin, Rodrigues-Viguier, Clément, Roques, Gisele, Roger, Maxime, Saez, Thomas, Terrée, Guillaume, Villefranque, Najda, Vourc’h, Thomas, Yaacoub, Daniel
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2023
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10079137/
https://www.ncbi.nlm.nih.gov/pubmed/37023098
http://dx.doi.org/10.1371/journal.pone.0283681
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author Tregan, Jean Marc
Amestoy, Jean Luc
Bati, Megane
Bezian, Jean-Jacques
Blanco, Stéphane
Brunel, Laurent
Caliot, Cyril
Charon, Julien
Cornet, Jean-Francois
Coustet, Christophe
d’Alençon, Louis
Dauchet, Jeremi
Dutour, Sebastien
Eibner, Simon
El Hafi, Mouna
Eymet, Vincent
Farges, Olivier
Forest, Vincent
Fournier, Richard
Galtier, Mathieu
Gattepaille, Victor
Gautrais, Jacques
He, Zili
Hourdin, Frédéric
Ibarrart, Loris
Joly, Jean-Louis
Lapeyre, Paule
Lavieille, Pascal
Lecureux, Marie-Helene
Lluc, Jacques
Miscevic, Marc
Mourtaday, Nada
Nyffenegger-Péré, Yaniss
Pelissier, Lionel
Penazzi, Lea
Piaud, Benjamin
Rodrigues-Viguier, Clément
Roques, Gisele
Roger, Maxime
Saez, Thomas
Terrée, Guillaume
Villefranque, Najda
Vourc’h, Thomas
Yaacoub, Daniel
author_facet Tregan, Jean Marc
Amestoy, Jean Luc
Bati, Megane
Bezian, Jean-Jacques
Blanco, Stéphane
Brunel, Laurent
Caliot, Cyril
Charon, Julien
Cornet, Jean-Francois
Coustet, Christophe
d’Alençon, Louis
Dauchet, Jeremi
Dutour, Sebastien
Eibner, Simon
El Hafi, Mouna
Eymet, Vincent
Farges, Olivier
Forest, Vincent
Fournier, Richard
Galtier, Mathieu
Gattepaille, Victor
Gautrais, Jacques
He, Zili
Hourdin, Frédéric
Ibarrart, Loris
Joly, Jean-Louis
Lapeyre, Paule
Lavieille, Pascal
Lecureux, Marie-Helene
Lluc, Jacques
Miscevic, Marc
Mourtaday, Nada
Nyffenegger-Péré, Yaniss
Pelissier, Lionel
Penazzi, Lea
Piaud, Benjamin
Rodrigues-Viguier, Clément
Roques, Gisele
Roger, Maxime
Saez, Thomas
Terrée, Guillaume
Villefranque, Najda
Vourc’h, Thomas
Yaacoub, Daniel
author_sort Tregan, Jean Marc
collection PubMed
description It was recently shown that radiation, conduction and convection can be combined within a single Monte Carlo algorithm and that such an algorithm immediately benefits from state-of-the-art computer-graphics advances when dealing with complex geometries. The theoretical foundations that make this coupling possible are fully exposed for the first time, supporting the intuitive pictures of continuous thermal paths that run through the different physics at work. First, the theoretical frameworks of propagators and Green’s functions are used to demonstrate that a coupled model involving different physical phenomena can be probabilized. Second, they are extended and made operational using the Feynman-Kac theory and stochastic processes. Finally, the theoretical framework is supported by a new proposal for an approximation of coupled Brownian trajectories compatible with the algorithmic design required by ray-tracing acceleration techniques in highly refined geometry.
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spelling pubmed-100791372023-04-07 Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations Tregan, Jean Marc Amestoy, Jean Luc Bati, Megane Bezian, Jean-Jacques Blanco, Stéphane Brunel, Laurent Caliot, Cyril Charon, Julien Cornet, Jean-Francois Coustet, Christophe d’Alençon, Louis Dauchet, Jeremi Dutour, Sebastien Eibner, Simon El Hafi, Mouna Eymet, Vincent Farges, Olivier Forest, Vincent Fournier, Richard Galtier, Mathieu Gattepaille, Victor Gautrais, Jacques He, Zili Hourdin, Frédéric Ibarrart, Loris Joly, Jean-Louis Lapeyre, Paule Lavieille, Pascal Lecureux, Marie-Helene Lluc, Jacques Miscevic, Marc Mourtaday, Nada Nyffenegger-Péré, Yaniss Pelissier, Lionel Penazzi, Lea Piaud, Benjamin Rodrigues-Viguier, Clément Roques, Gisele Roger, Maxime Saez, Thomas Terrée, Guillaume Villefranque, Najda Vourc’h, Thomas Yaacoub, Daniel PLoS One Research Article It was recently shown that radiation, conduction and convection can be combined within a single Monte Carlo algorithm and that such an algorithm immediately benefits from state-of-the-art computer-graphics advances when dealing with complex geometries. The theoretical foundations that make this coupling possible are fully exposed for the first time, supporting the intuitive pictures of continuous thermal paths that run through the different physics at work. First, the theoretical frameworks of propagators and Green’s functions are used to demonstrate that a coupled model involving different physical phenomena can be probabilized. Second, they are extended and made operational using the Feynman-Kac theory and stochastic processes. Finally, the theoretical framework is supported by a new proposal for an approximation of coupled Brownian trajectories compatible with the algorithmic design required by ray-tracing acceleration techniques in highly refined geometry. Public Library of Science 2023-04-06 /pmc/articles/PMC10079137/ /pubmed/37023098 http://dx.doi.org/10.1371/journal.pone.0283681 Text en © 2023 Tregan et al https://creativecommons.org/licenses/by/4.0/This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Tregan, Jean Marc
Amestoy, Jean Luc
Bati, Megane
Bezian, Jean-Jacques
Blanco, Stéphane
Brunel, Laurent
Caliot, Cyril
Charon, Julien
Cornet, Jean-Francois
Coustet, Christophe
d’Alençon, Louis
Dauchet, Jeremi
Dutour, Sebastien
Eibner, Simon
El Hafi, Mouna
Eymet, Vincent
Farges, Olivier
Forest, Vincent
Fournier, Richard
Galtier, Mathieu
Gattepaille, Victor
Gautrais, Jacques
He, Zili
Hourdin, Frédéric
Ibarrart, Loris
Joly, Jean-Louis
Lapeyre, Paule
Lavieille, Pascal
Lecureux, Marie-Helene
Lluc, Jacques
Miscevic, Marc
Mourtaday, Nada
Nyffenegger-Péré, Yaniss
Pelissier, Lionel
Penazzi, Lea
Piaud, Benjamin
Rodrigues-Viguier, Clément
Roques, Gisele
Roger, Maxime
Saez, Thomas
Terrée, Guillaume
Villefranque, Najda
Vourc’h, Thomas
Yaacoub, Daniel
Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations
title Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations
title_full Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations
title_fullStr Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations
title_full_unstemmed Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations
title_short Coupling radiative, conductive and convective heat-transfers in a single Monte Carlo algorithm: A general theoretical framework for linear situations
title_sort coupling radiative, conductive and convective heat-transfers in a single monte carlo algorithm: a general theoretical framework for linear situations
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10079137/
https://www.ncbi.nlm.nih.gov/pubmed/37023098
http://dx.doi.org/10.1371/journal.pone.0283681
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