Parareal in time algorithm, time-dependent neutron diffusion equations, reduced model, parallel computation, hight performance computing

Salomon, Julien; Riahi, Mohamed Kamel; Maday, Yvon; Baudron, Anne-Marie; Lautard, Jean-Jacques

Salomon, Julien; Riahi, Mohamed Kamel; Maday, Yvon; Baudron, Anne-Marie; Lautard, Jean-Jacques (2011), Parareal in time algorithm, time-dependent neutron diffusion equations, reduced model, parallel computation, hight performance computing. https://basepub.dauphine.fr/handle/123456789/9876

Type

Document de travail / Working paper

Lien vers un document non conservé dans cette base

http://hal.archives-ouvertes.fr/hal-00722802

Date

2011

Éditeur

Université Paris-Dauphine

Ville d’édition

Paris

Métadonnées

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Auteur(s)

Salomon, Julien
Riahi, Mohamed Kamel
Maday, Yvon
Baudron, Anne-Marie
Lautard, Jean-Jacques

Résumé (EN)

The accurate knowledge of the time-dependent spatial flux distribution in nuclear reactor is required for nuclear safety and design. The motivation behind the development of parallel methods for solving the energy-, space-, and time-dependent kinetic equations is not only the challenge of developing a method for solving a large set of coupled partial differential equations, but also a real need to predict the performance and assess the safety of large commercial reactors, both these presently operating and those being designed for the future. Numerical results show the efficiency of the parareal method on large light water reactor transient model.

Mots-clés

parareal in time algorithm; parallel solver; kinetic of neutrons