We present a new fast multipole method for particle simulations. The main feature of our algorithm is that it does not require the implementation of multipole expansions of the underlying kernel, and it is based only on kernel evaluations. Instead of using analytic expansions to represent the potential generated by sources inside a box of the hierarchical FMM tree, we use a continuous distribution of an equivalent density on a surface enclosing the box. To find this equivalent density we match its potential to the potential of the original sources at a surface, in the far field, by solving local Dirichlet-type boundary value problems. The far field evaluations are sparsified with singular value decomposition in 2D or fast Fourier transforms...
A number of physics problems can be modeled by a set of N elements, which have pair-wise interaction...
AbstractStandard implementations of the fast multipole method, which compute fields due to point sou...
In this dissertation, we extend Greengard and Rokhlin's seminal work on fast multipole method (FMM) ...
We present a new fast multipole method for particle simulations. The main feature of our algorithm i...
We present a new adaptive fast multipole algorithm and its parallel implementation. The algorithm is...
For more than two decades, several forms of fast multipole methods have been extremely successful in...
We provide all necessary theoretical statements concerning the hydrodynamical double layer potential...
AbstractThis paper presents a parallel version of the fast multipole method (FMM). The FMM is a rece...
This program has been imported from the CPC Program Library held at Queen's University Belfast (1969...
Abstract. A version of the fast multipole method (FMM) is described for charge distributions on the ...
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computatio...
Panel methods are commonly used in computational fluid dynamics for the solution of potential flow p...
A number of physics problems can be modeled by a set of N elements, which have pair-wise interaction...
AbstractWe present a fast, adaptive multiresolution algorithm for applying integral operators with a...
A grid-based fast multipole method (GB-FMM) for optimizing three-dimensional (3D) numerical molecula...
A number of physics problems can be modeled by a set of N elements, which have pair-wise interaction...
AbstractStandard implementations of the fast multipole method, which compute fields due to point sou...
In this dissertation, we extend Greengard and Rokhlin's seminal work on fast multipole method (FMM) ...
We present a new fast multipole method for particle simulations. The main feature of our algorithm i...
We present a new adaptive fast multipole algorithm and its parallel implementation. The algorithm is...
For more than two decades, several forms of fast multipole methods have been extremely successful in...
We provide all necessary theoretical statements concerning the hydrodynamical double layer potential...
AbstractThis paper presents a parallel version of the fast multipole method (FMM). The FMM is a rece...
This program has been imported from the CPC Program Library held at Queen's University Belfast (1969...
Abstract. A version of the fast multipole method (FMM) is described for charge distributions on the ...
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computatio...
Panel methods are commonly used in computational fluid dynamics for the solution of potential flow p...
A number of physics problems can be modeled by a set of N elements, which have pair-wise interaction...
AbstractWe present a fast, adaptive multiresolution algorithm for applying integral operators with a...
A grid-based fast multipole method (GB-FMM) for optimizing three-dimensional (3D) numerical molecula...
A number of physics problems can be modeled by a set of N elements, which have pair-wise interaction...
AbstractStandard implementations of the fast multipole method, which compute fields due to point sou...
In this dissertation, we extend Greengard and Rokhlin's seminal work on fast multipole method (FMM) ...