Boundary Element Methods in Engineering and Sciences

Computational methods have made significant contributions in all fields of engineering mechanics. Of these the finite element and the finite difference methods have become widely known and gained widespread acceptance. The last two decades have seen the emergence of an equally versatile and powerful

Computational methods have made significant contributions in all fields of engineering mechanics. Of these the finite element and the finite difference methods have become widely known and gained widespread acceptance. The last two decades have seen the emergence of an equally versatile and powerful

Differential Forms and Boundary Integral Equations for Maxwell-Type Problems.- Discrete Electromagnetism with Shape Forms of Higher Polynomial Degree.- Additive Schwarz Methods for the hp Version of the Boundary Element Method in R3.- Fast Boundary Element Methods for Industrial Applications in Mag

<p><p>This volume contains eight state of the art contributions on mathematical aspects and applications of fast boundary element methods in engineering and industry. This covers the analysis and numerics of boundary integral equations by using differential forms, preconditioning of hp boundary elem

The fast multipole method is one of the most important algorithms in computing developed in the 20th century. Along with the fast multipole method, the boundary element method (BEM) has also emerged, as a powerful method for modeling large-scale problems. BEM models with millions of unknowns on the

The fast multipole method is one of the most important algorithms in computing developed in the 20th century. Along with the fast multipole method, the boundary element method (BEM) has also emerged, as a powerful method for modeling large-scale problems. BEM models with millions of unknowns on the