Title :
Staircase-free finite-difference time-domain formulation for general materials in complex geometries
Author :
Dridi, K.H. ; Hesthaven, Jan S. ; Ditkowski, Adi
Author_Institution :
Opt. & Fluid Dynamics Dept., Riso Nat. Lab., Roskilde, Denmark
fDate :
5/1/2001 12:00:00 AM
Abstract :
A stable Cartesian grid staircase-free finite-difference time-domain formulation for arbitrary material distributions in general geometries is introduced. It is shown that the method exhibits higher accuracy than the classical Yee (1966) scheme for complex geometries since the computational representation of physical structures is not of a staircased nature. Furthermore, electromagnetic boundary conditions are correctly enforced. The method significantly reduces simulation times as fewer points per wavelength are needed to accurately resolve the wave and the geometry. Both perfect electric conductors and dielectric structures have been investigated. Numerical results are presented and discussed
Keywords :
Maxwell equations; conductors (electric); dielectric bodies; dielectric waveguides; finite difference time-domain analysis; photonic band gap; resonators; FDTD; Maxwell´s equations; PEC resonator; complex geometries; computational representation; dielectric structures; dielectric waveguiding material; electromagnetic boundary conditions; general materials; lD PEC cavity; material distribution; perfect electric conductors; photonic crystal/bandgap structures; physical structures; plane wave incidence; simulation time; spatial second-order accuracy; stable Cartesian grid; staircase-free finite-difference time-domain; subwavelength diffractive optical elements; Boundary conditions; Finite difference methods; Geometrical optics; Geometry; Integrated optics; Maxwell equations; Optical devices; Partial differential equations; Solid modeling; Time domain analysis;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
