International audienceWe analyse $a\ posteriori$ error estimates for the discretization of the neutron diffusion equations with mixed finite elements. We provide guaranteed and locally efficient estimators on a base block equation, the one-group neutron diffusion equation. We pay particular attention to AMR strategies on Cartesian meshes, since such structures are common for nuclear reactor core applications. We exhibit a robust marker strategy for this specific constraint, the $direction\ marker$ strategy. The approach is further extended to a Domain Decomposition Method, the so-called DD+$L^2$ jumps method, as well as to the multigroup neutron diffusion equation
Several polynomial finite elements of nodal type are introduced that should lead to convergence of O...
The numerical solution of time dependent neutron diffusion approximation to the transport equation i...
172 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1980.The multigroup neutron diffus...
We analyse $a\ posteriori$ error estimates for the discretization of the neutron diffusion equations...
We analyse a posteriori error estimates for the discretization of the neutron diffusion equations wi...
The neutron transport equation can be used to model the physics of the nuclear reactor core. Its sol...
International audienceWe study first the convergence of the finite element approximation of the mixe...
Finite difference techniques are used to solve a variety of differential equations. For the neutron ...
Computer codes involving neutron transport theory for nuclear engineering applications always requir...
We develop the a posteriori error analysis for mixed-primal and fully-mixed finite element methods a...
We present in this paper a unified framework for a posteriori error estimation in the finite volume ...
Abstract. In classical mixed finite element method, the choice of the finite element approximating s...
Error norms for three variants of Larsen's benchmark problem are evaluated using three numerical met...
The Continuous Galerkin Virtual Element Method (CG-VEM) is a recent innovation in spatial discretisa...
We study the spatial discretization, in a fully discrete scheme, for the numerical solution of a mod...
Several polynomial finite elements of nodal type are introduced that should lead to convergence of O...
The numerical solution of time dependent neutron diffusion approximation to the transport equation i...
172 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1980.The multigroup neutron diffus...
We analyse $a\ posteriori$ error estimates for the discretization of the neutron diffusion equations...
We analyse a posteriori error estimates for the discretization of the neutron diffusion equations wi...
The neutron transport equation can be used to model the physics of the nuclear reactor core. Its sol...
International audienceWe study first the convergence of the finite element approximation of the mixe...
Finite difference techniques are used to solve a variety of differential equations. For the neutron ...
Computer codes involving neutron transport theory for nuclear engineering applications always requir...
We develop the a posteriori error analysis for mixed-primal and fully-mixed finite element methods a...
We present in this paper a unified framework for a posteriori error estimation in the finite volume ...
Abstract. In classical mixed finite element method, the choice of the finite element approximating s...
Error norms for three variants of Larsen's benchmark problem are evaluated using three numerical met...
The Continuous Galerkin Virtual Element Method (CG-VEM) is a recent innovation in spatial discretisa...
We study the spatial discretization, in a fully discrete scheme, for the numerical solution of a mod...
Several polynomial finite elements of nodal type are introduced that should lead to convergence of O...
The numerical solution of time dependent neutron diffusion approximation to the transport equation i...
172 p.Thesis (Ph.D.)--University of Illinois at Urbana-Champaign, 1980.The multigroup neutron diffus...