AbstractDiscretisation of the integral equations of acoustic scattering yields large dense systems of linear equations. Using the fast multipole method, an approximate solution to these systems can be computed with a low operation count. When implementing the method, various infinite sums must be truncated. In this paper, sharp computable bounds on the errors of these truncations are derived, which could form the basis for an automatic selection of truncation length. This choice will guarantee a given solution accuracy whilst minimising the operation count of the fast multipole algorithm
Rapporteurs de These : M. Nedelec Jean-Claude et M. Joly Patrick ; President de soutenance : M. Hano...
The Laplace and Helmholtz equations are two of the most important partial differential equations (PD...
International audienceThis work presents a new Fast Multipole Method (FMM) based on plane wave expan...
AbstractDiscretisation of the integral equations of acoustic scattering yields large dense systems o...
We perform a complete study of the truncation error of the Gegenbauer series. This series yields a...
We perform a complete study of the truncation error of the Jacobi-Anger series. This series expand...
The multilevel fast multipole algorithm is based on the multipole expansion, which has numerical err...
International audienceThis paper presents an empirical study of the accuracy of multipole expansions...
For more than two decades, several forms of fast multipole methods have been extremely successful in...
The fast multipole method (FMM) was developed by Rokhlin to solve acoustic scattering problems very ...
In this paper the theoretical foundation of the fast multipole method applied to problems involving ...
Described as one of the best ten algorithms of the 20th century, the fast multipole formalism applie...
We examine the practical implementation of a fast multipole method algorithm for the rapid summation...
The development of a fast multipole method accelerated iterative solution of the boundary element e...
Novel formulas are presented that allow the rapid estimation of the number of terms L that needs to ...
Rapporteurs de These : M. Nedelec Jean-Claude et M. Joly Patrick ; President de soutenance : M. Hano...
The Laplace and Helmholtz equations are two of the most important partial differential equations (PD...
International audienceThis work presents a new Fast Multipole Method (FMM) based on plane wave expan...
AbstractDiscretisation of the integral equations of acoustic scattering yields large dense systems o...
We perform a complete study of the truncation error of the Gegenbauer series. This series yields a...
We perform a complete study of the truncation error of the Jacobi-Anger series. This series expand...
The multilevel fast multipole algorithm is based on the multipole expansion, which has numerical err...
International audienceThis paper presents an empirical study of the accuracy of multipole expansions...
For more than two decades, several forms of fast multipole methods have been extremely successful in...
The fast multipole method (FMM) was developed by Rokhlin to solve acoustic scattering problems very ...
In this paper the theoretical foundation of the fast multipole method applied to problems involving ...
Described as one of the best ten algorithms of the 20th century, the fast multipole formalism applie...
We examine the practical implementation of a fast multipole method algorithm for the rapid summation...
The development of a fast multipole method accelerated iterative solution of the boundary element e...
Novel formulas are presented that allow the rapid estimation of the number of terms L that needs to ...
Rapporteurs de These : M. Nedelec Jean-Claude et M. Joly Patrick ; President de soutenance : M. Hano...
The Laplace and Helmholtz equations are two of the most important partial differential equations (PD...
International audienceThis work presents a new Fast Multipole Method (FMM) based on plane wave expan...