Stable marching-on-in-time algorithm capable of handling multiple excitations – application to wire junction problems

In this work, a stable marching-on-in-time method is presented to obtain a scattering response from arbitrary wire structures illuminated by a Gaussian plane wave directly in the time domain (TD). Contrary to all the available TD algorithms until now, the present procedure, besides being stable, is...

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Bibliographic Details
Published in:IET microwaves, antennas & propagation antennas & propagation, 2018-03, Vol.12 (4), p.472-478
Main Author: Rao, Sadasiva M
Format: Article
Language:English
Subjects:
arbitrary wire structures
discrete Fourier transforms
electromagnetic wave scattering
frequency domain solution
frequency‐domain analysis
functions
Gaussian plane wave
inverse discrete Fourier transform
inverse transforms
method of moments
multiple excitations handling
scattering response
space variable Gaussian function
Special Issue: Selected Papers from the 11th European Conference on Antennas and Propagation (EuCAP 2017)
stable marching‐on‐in‐time algorithm
standard pulse functions
testing procedure
time domain
time‐domain analysis
time‐shifted Gaussian function
wire junction problems
wires (electric)
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Summary:In this work, a stable marching-on-in-time method is presented to obtain a scattering response from arbitrary wire structures illuminated by a Gaussian plane wave directly in the time domain (TD). Contrary to all the available TD algorithms until now, the present procedure, besides being stable, is also capable of handling multiple excitations in a trivial manner. The new procedure is based on the conventional method of moments and utilises standard pulse functions for expansion of the space variable and time-shifted Gaussian functions for the time variable. The testing procedure is accomplished by collocation. The numerical results obtained using the new procedure are validated by comparing with the data obtained from the frequency domain solution using the same modelling scheme and performing inverse discrete Fourier transform.
ISSN:1751-8725
1751-8733
1751-8733
DOI:10.1049/iet-map.2017.0616