AbstractThis paper presents a parallel version of the fast multipole method (FMM). The FMM is a recently developed scheme for the evaluation of the potential and force fields in systems of particles whose interactions are Coulombic or gravitational in nature. The sequential method requires O(N) operations to obtain the fields due to N charges, rather than the O(N2) operations required by the direct calculation. Here, we describe the modifications necessary for implementation of the method on parallel architectures and show that the expected time requirements grow as log N when using N processors. Numerical results are given for a shared memory machine (the Encore Multimax 320)
We present a new adaptive fast multipole algorithm and its parallel implementation. The algorithm is...
We have implemented the fast multipole method (FMM) on a special-purpose computer GRAPE (GRAvity piP...
Algorithms and working expressions for a grid-based fast multipole method (GB-FMM) have been develop...
AbstractThis paper presents a parallel version of the fast multipole method (FMM). The FMM is a rece...
This thesis describes the Fast Multipole Method (FMM). The method reduces the complexity of the Coul...
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computatio...
Evaluating the energy of a system of N bodies interacting via a pairwise potential is naïvely an O(N...
A significant and computationally most demanding part of molecular dynamics simulations is the calcu...
This thesis presents a top to bottom analysis on designing and implementing fast algorithms for curr...
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computatio...
N-body pairwise interactions are ubiquitous in scientific areas such as astrophysics, fluids mechani...
<b>Invited Lecture at the SIAM <i>"Encuentro Nacional de Ingeniería Matemática,"</i> at Pontificia U...
The Fast Multipole Method allows the rapid evaluation of sums of radial basis functions centered at ...
The approximate computation of all gravitational forces between N interacting particles via the fast...
This article introduces a novel approach to increase the performances of N-body simulations. In an N...
We present a new adaptive fast multipole algorithm and its parallel implementation. The algorithm is...
We have implemented the fast multipole method (FMM) on a special-purpose computer GRAPE (GRAvity piP...
Algorithms and working expressions for a grid-based fast multipole method (GB-FMM) have been develop...
AbstractThis paper presents a parallel version of the fast multipole method (FMM). The FMM is a rece...
This thesis describes the Fast Multipole Method (FMM). The method reduces the complexity of the Coul...
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computatio...
Evaluating the energy of a system of N bodies interacting via a pairwise potential is naïvely an O(N...
A significant and computationally most demanding part of molecular dynamics simulations is the calcu...
This thesis presents a top to bottom analysis on designing and implementing fast algorithms for curr...
Solving an N-body problem, electrostatic or gravitational, is a crucial task and the main computatio...
N-body pairwise interactions are ubiquitous in scientific areas such as astrophysics, fluids mechani...
<b>Invited Lecture at the SIAM <i>"Encuentro Nacional de Ingeniería Matemática,"</i> at Pontificia U...
The Fast Multipole Method allows the rapid evaluation of sums of radial basis functions centered at ...
The approximate computation of all gravitational forces between N interacting particles via the fast...
This article introduces a novel approach to increase the performances of N-body simulations. In an N...
We present a new adaptive fast multipole algorithm and its parallel implementation. The algorithm is...
We have implemented the fast multipole method (FMM) on a special-purpose computer GRAPE (GRAvity piP...
Algorithms and working expressions for a grid-based fast multipole method (GB-FMM) have been develop...