Geodesic
ALBERT - SOFTWARE FOR SCIENTIFIC COMPUTATIONS AND APPLICATION
Acta mathematica Universitatis Comenianae, Tome 70 (2001) no. 1 
A. Schmidt; K. G. Siebert. ALBERT - SOFTWARE  FOR  SCIENTIFIC  COMPUTATIONS
                                       AND  APPLICATION. Acta mathematica Universitatis Comenianae, Tome 70 (2001) no. 1. http://geodesic.mathdoc.fr/item/AMUC_2001_70_1_a6/
@article{AMUC_2001_70_1_a6,
     author = {A. Schmidt and K. G. Siebert},
     title = {ALBERT - {SOFTWARE}  {FOR}  {SCIENTIFIC}  {COMPUTATIONS
}                                       {AND}  {APPLICATION}},
     journal = {Acta mathematica Universitatis Comenianae},
     year = {2001},
     volume = {70},
     number = {1},
     url = {http://geodesic.mathdoc.fr/item/AMUC_2001_70_1_a6/}
}
TY  - JOUR
AU  - A. Schmidt
AU  - K. G. Siebert
TI  - ALBERT - SOFTWARE  FOR  SCIENTIFIC  COMPUTATIONS
                                       AND  APPLICATION
JO  - Acta mathematica Universitatis Comenianae
PY  - 2001
VL  - 70
IS  - 1
UR  - http://geodesic.mathdoc.fr/item/AMUC_2001_70_1_a6/
ID  - AMUC_2001_70_1_a6
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%A K. G. Siebert
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                                       AND  APPLICATION
%J Acta mathematica Universitatis Comenianae
%D 2001
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%U http://geodesic.mathdoc.fr/item/AMUC_2001_70_1_a6/
%F AMUC_2001_70_1_a6

Voir la notice de l'article provenant de la source Comenius University

Adaptive finite element methods are a modern, widely used tool which make realistic computations feasible, even in three space dimensions. We describe the basic ideas and ingredients of adaptive FEM and the implementation of our toolbox \ALBERT. The design of \ALBERT is based on the natural hierarchy of locally refined meshes and an abstract concept of general finite element spaces. As a result, dimension independent programming of applications is possible. Numerical results from applications in two and three space dimensions demonstrate the flexibility of \ALBERT.