Title :
2D FDTD modelling of objects with curved boundaries, using embedded boundary orthogonal grids
Author :
Pan, G.W. ; Cheng, D.-H. ; Gilbert, B.K.
Author_Institution :
Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ, USA
fDate :
10/1/2000 12:00:00 AM
Abstract :
An FDTD algorithm was developed using an embedded boundary orthogonal grid system. The algorithm is based on the complex Laplace equation to implement conformal mapping that minimises the magnitudes of the mesh gradients and therefore leads to the smoothest coordinate line distribution over the solution domain. In conjunction with the global rectangular meshes, the local non-orthogonal grids provide versatility of geometry. There is no need to perform interpolation on the boundaries between the local and global grids. As a result, computational time and memory requirements are substantially reduced. The field solution to the unbounded Laplace equation in nonorthogonal coordinates is obtained, and is used as the exciting source to expedite the convergence of the FDTD computations. Numerical examples show good agreement with the results presented in previous publications, both guided wave and scattering problems
Keywords :
Maxwell equations; convergence of numerical methods; electromagnetic wave scattering; finite difference time-domain analysis; mesh generation; transmission line theory; 2D FDTD modelling; complex Laplace equation; computational time; conformal mapping; convergence; curved boundary objects; embedded boundary orthogonal grid system; exciting source; field solution; global rectangular meshes; guided wave problems; local non-orthogonal grids; memory requirements; mesh gradients; nonorthogonal coordinates; scattering problem; smoothest coordinate line distribution; unbounded Laplace equation;
Journal_Title :
Microwaves, Antennas and Propagation, IEE Proceedings
DOI :
10.1049/ip-map:20000738
