Title :
Fast Computation of the Nonlocal Boundary Condition in Finite Difference Parabolic Equation Radiowave Propagation Simulations
Author_Institution :
Commun. & Signal Process. Group, Univ. of Warwick, Coventry
fDate :
6/1/2008 12:00:00 AM
Abstract :
Finite difference parabolic equation method (FD-PEM) codes using a nonlocal boundary condition to model radiowave propagation over electrically large domains, require the computation of time consuming spatial convolution integrals. For the first time, we propose the use of recursive convolution (RC) with vector fitting (VF) to reduce this computational burden. RC is based on the ability to express functions as a sum of exponential terms. This is achieved using the VF method. Details of the RC formulation applied in a two-dimensional (2D) Wide-angle FD-PEM (WA-FD-PEM) are presented together with 2D simulations which demonstrate the computational speed and accuracy of the synthesized RC-WA-FD-PEM code.
Keywords :
boundary-value problems; convolutional codes; finite difference methods; parabolic equations; radiowave propagation; 2D wide-angle FD-PEM codes; finite difference parabolic equation radiowave propagation simulation; nonlocal boundary condition; recursive convolution; spatial convolution integral; vector fitting; Boundary conditions; Computational modeling; Convolution; Difference equations; Finite difference methods; Integral equations; Laser radar; Optical devices; Radar cross section; Radiowave propagation; Finite-difference parabolic equation method (FD-PEM); radiowave propagation; recursive convolution (RC); vector fitting (VF);
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2008.923341
