The fast multipole method in the differential algebra framework

We study integral methods applied to the resolution of the Maxwell equations where the linear system is solved using an iterative method which requires only matrix-vector products. The fast multipole method (FMM) is one of the most efficient methods used to perform matrix-vector products and acceler

We apply a new method of reducing the computational effort required for solution of the Electric Field Integral Equation used for modelling microstrip structures. The Fast Multipole Method is used to compute the radiation pattern and input impedance of single layer microstrip antennas.

The numerical solution to N-body problems in gravitation or electrostatics has traditionally been obtained via particle-in-cell methods (PLC) since direct evaluation of all pairwise interparticle forces, requiring t!~( N 2) operations, is too expensive. Recently, hierarchical solvers, which use tree

The most efficient and proper standard method for simulating charged or dipolar systems is the Ewald method, which asymptotically scales as N 3/2 where N is the number of charges. However, recently the "fast multipole method" (FMM) which scales linearly with N has been developed. The break-even of t