Abstract :
Summary form only given. To model electromagnetic wave interactions on the complicated structures in microwave remote-sensing, devices used in the microwave and optical wave regions, and material sciences, we need to process ultra wideband signals on such structures. So far we have two types of Maxwell solvers. One type incudes techniques, such as the finite element method, the generalized multipoles method, and the boundary element method, for solving boundary value problems about the second order partial differential equation called the Helmholtz equation. The other is a direct Maxwell, for example, the finite difference time domain method in which Maxwell´s equations, denoted by a set of first order coupled partial differential equations, can be solved. The author discusses the development of efficient and stable numerical algorithms for use as Maxwell solvers.
Keywords :
Helmholtz equations; Maxwell equations; boundary-value problems; computational electromagnetics; electromagnetic field theory; finite difference time-domain analysis; finite element analysis; light propagation; microwave propagation; partial differential equations; FDTD; FEM; Helmholtz equation; Maxwell equations; Maxwell solvers; PDE; boundary element method; computational electromagnetics; electromagnetic wave interaction modelling; finite difference time domain method; finite element method; generalized multipoles method; material sciences; microwave; numerical algorithms; optical wave region; partial differential equation; ultra wideband signals; Computational electromagnetics; Electromagnetic modeling; Electromagnetic scattering; Maxwell equations; Microwave devices; Optical devices; Optical materials; Partial differential equations; Remote sensing; Ultra wideband technology;
