Title :
An efficient Integral equation-based electromagnetic propagation model for terrain
Author_Institution :
Dept. of Comput. Sci., Trinity Coll. Dublin, Ireland
fDate :
5/1/2005 12:00:00 AM
Abstract :
An improved fast integral equation (IE) method to evaluate the slow fading signal at 970 MHz over terrain is described here. An 11.1 km, two-dimensional, semi-rural terrain profile is modeled as a series of interconnecting perfectly electrically conducting (PEC) segments. The algorithm achieves its computational speed by approximating the local surface current as a constant-amplitude sinusoid. An appropriately scaled value of this current can be used to quickly compute the scattered field. This process takes 0.05 s on a PC with a 2.2 GHz Pentium 4 processor giving a standard deviation of 15.57 dB and 9.48 dB from the full-wave solution and measurements, respectively. Where the local surface current is modeled as having a Rayleigh distributed envelope the computation time is 2.66 s but a reduction in the standard deviation to 3.07 dB and 8.77 dB from the full-wave solution and measurements ensues.
Keywords :
Rayleigh channels; computational electromagnetics; conducting bodies; integral equations; radiowave propagation; 0.05 s; 11.1 km; 2.2 GHz; 970 MHz; PEC; Pentium 4-processor; Rayleigh channel; electromagnetic propagation; fast integral equation method; perfectly electrically conducting; semirural terrain profile; slow fading signal; Current measurement; Distributed computing; Electromagnetic modeling; Electromagnetic propagation; Electromagnetic scattering; Fading; Integral equations; Measurement standards; Rayleigh scattering; Time measurement; Integral equations; Rayleigh channels; modeling; propagation;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2005.846812
