Numerical approximations for a nonlocal evolution equation

In this paper we study numerical approximations of continuous solutions to the nonlocal p-Laplacian type diffusion equation, ut(t, x) = ∫Ω J(x - y)|u(t, y) - u(t, x)|p-2(u(t, y) - u(t, x)) dy. First, we find that a semidiscretization in space of this problem gives rise to an ODE system whose solutio...

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Autores principales: Pérez-Llanos, M., Rossi, J.D.
Formato: JOUR
Materias:
Neumann boundary conditions
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Neumann boundary condition
Laplace transforms
Partial differential equations
Boundary conditions
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_00361429_v49_n5_p2103_PerezLlanos
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
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spelling todo:paper_00361429_v49_n5_p2103_PerezLlanos2023-10-03T14:47:45Z Numerical approximations for a nonlocal evolution equation Pérez-Llanos, M. Rossi, J.D. Neumann boundary conditions Nonlocal diffusion Numerical approximations P-Laplacian Sandpiles Neumann boundary condition Nonlocal diffusion Numerical approximations P-Laplacian Sandpiles Laplace transforms Partial differential equations Boundary conditions In this paper we study numerical approximations of continuous solutions to the nonlocal p-Laplacian type diffusion equation, ut(t, x) = ∫Ω J(x - y)|u(t, y) - u(t, x)|p-2(u(t, y) - u(t, x)) dy. First, we find that a semidiscretization in space of this problem gives rise to an ODE system whose solutions converge uniformly to the continuous one as the mesh size goes to zero. Moreover, the semidiscrete approximation shares some properties of the continuous problem: it preserves the total mass and the solution converges to the mean value of the initial condition as t goes to infinity. Next, we also discretize the time variable and present a totally discrete method which also enjoys the above mentioned properties. In addition, we investigate the limit as p goes to infinity in these approximations and obtain a discrete model for the evolution of a sandpile. Finally, we present some numerical experiments that illustrate our results. © by SIAM. Unauthorized reproduction of this article is prohibited. © 2011 Society for Industrial and Applied Mathematics. Fil:Rossi, J.D. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00361429_v49_n5_p2103_PerezLlanos
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Neumann boundary conditions
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Neumann boundary condition
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Laplace transforms
Partial differential equations
Boundary conditions
spellingShingle Neumann boundary conditions
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Neumann boundary condition
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Laplace transforms
Partial differential equations
Boundary conditions
Pérez-Llanos, M.
Rossi, J.D.
Numerical approximations for a nonlocal evolution equation
topic_facet Neumann boundary conditions
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Neumann boundary condition
Nonlocal diffusion
Numerical approximations
P-Laplacian
Sandpiles
Laplace transforms
Partial differential equations
Boundary conditions
description In this paper we study numerical approximations of continuous solutions to the nonlocal p-Laplacian type diffusion equation, ut(t, x) = ∫Ω J(x - y)|u(t, y) - u(t, x)|p-2(u(t, y) - u(t, x)) dy. First, we find that a semidiscretization in space of this problem gives rise to an ODE system whose solutions converge uniformly to the continuous one as the mesh size goes to zero. Moreover, the semidiscrete approximation shares some properties of the continuous problem: it preserves the total mass and the solution converges to the mean value of the initial condition as t goes to infinity. Next, we also discretize the time variable and present a totally discrete method which also enjoys the above mentioned properties. In addition, we investigate the limit as p goes to infinity in these approximations and obtain a discrete model for the evolution of a sandpile. Finally, we present some numerical experiments that illustrate our results. © by SIAM. Unauthorized reproduction of this article is prohibited. © 2011 Society for Industrial and Applied Mathematics.
format JOUR
author Pérez-Llanos, M.
Rossi, J.D.
author_facet Pérez-Llanos, M.
Rossi, J.D.
author_sort Pérez-Llanos, M.
title Numerical approximations for a nonlocal evolution equation
title_short Numerical approximations for a nonlocal evolution equation
title_full Numerical approximations for a nonlocal evolution equation
title_fullStr Numerical approximations for a nonlocal evolution equation
title_full_unstemmed Numerical approximations for a nonlocal evolution equation
title_sort numerical approximations for a nonlocal evolution equation
url http://hdl.handle.net/20.500.12110/paper_00361429_v49_n5_p2103_PerezLlanos
work_keys_str_mv AT perezllanosm numericalapproximationsforanonlocalevolutionequation
AT rossijd numericalapproximationsforanonlocalevolutionequation
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