VAGO Method for the solution of elliptic second‐order boundary value problems

VAGO Method for the solution of elliptic second‐order boundary value problems

Mathematical physics problems are often formulated using differential operators of vector analysis, i.e. invariant operators of first order, namely, divergence, gradient and rotor (curl) operators. In approximation of such problems it is natural to employ similar operator formulations for grid probl...

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Bibliographic Details
Main Authors: Nikolay Vabishchevich, Petr Vabishchevich
Format: Article
Language:English
Published: Vilnius Gediminas Technical University 2010-11-01
Series:Mathematical Modelling and Analysis
Subjects:
finite difference method
unstructured grids
Delaunay triangulation
Voronoi diagrams
convection‐diffusion problems
Online Access:https://journals.vgtu.lt/index.php/MMA/article/view/6042
Description
Summary:Mathematical physics problems are often formulated using differential operators of vector analysis, i.e. invariant operators of first order, namely, divergence, gradient and rotor (curl) operators. In approximation of such problems it is natural to employ similar operator formulations for grid problems. The VAGO (Vector Analysis Grid Operators) method is based on such a methodology. In this paper the vector analysis difference operators are constructed using the Delaunay triangulation and the Voronoi diagrams. Further the VAGO method is used to solve approximately boundary value problems for the general elliptic equation of second order. In the convection‐diffusion‐reaction equation the diffusion coefficient is a symmetric tensor of second order. First published online: 10 Feb 2011
ISSN:1392-6292
1648-3510

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