IEICE TRANSACTIONS on Electronics
Numerical Analysis of 3-D Scattering Problems Using the Yasuura Method
Summary :
The Yasuura method is effective for calculating scattering problems by bodies of revolution. However dealing with 3-D scattering problems, we need to solve bigger size dense matrix equations. One of the methods to solve 3-D scattering is to use multipole expansion which accelerate the convergence rate of solutions on the Yasuura method. We introduce arrays of multipoles and obtain rapidly converging solutions. Therefore we can calculate scattering properties over a relatively wide frequency range and clarify scattering properties such as frequency dependence, shape dependence, and polarization dependence of 3-D scattering from perfectly conducting scatterer. In these numerical results, we keep at least 2 significant figures.
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- IEICE TRANSACTIONS on Electronics Vol.E79-C No.10 pp.1358-1363
- Publication Date
- 1996/10/25
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- Special Section PAPER (Special Issue on Electromagnetic Theory-Foundations and Applications)
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Mitsunori KAWANO, Hiroyoshi IKUNO, Masahiko NISHIMOTO, "Numerical Analysis of 3-D Scattering Problems Using the Yasuura Method" in IEICE TRANSACTIONS on Electronics,
vol. E79-C, no. 10, pp. 1358-1363, October 1996, doi: .
Abstract: The Yasuura method is effective for calculating scattering problems by bodies of revolution. However dealing with 3-D scattering problems, we need to solve bigger size dense matrix equations. One of the methods to solve 3-D scattering is to use multipole expansion which accelerate the convergence rate of solutions on the Yasuura method. We introduce arrays of multipoles and obtain rapidly converging solutions. Therefore we can calculate scattering properties over a relatively wide frequency range and clarify scattering properties such as frequency dependence, shape dependence, and polarization dependence of 3-D scattering from perfectly conducting scatterer. In these numerical results, we keep at least 2 significant figures.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e79-c_10_1358/_p
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@ARTICLE{e79-c_10_1358,
author={Mitsunori KAWANO, Hiroyoshi IKUNO, Masahiko NISHIMOTO, },
journal={IEICE TRANSACTIONS on Electronics},
title={Numerical Analysis of 3-D Scattering Problems Using the Yasuura Method},
year={1996},
volume={E79-C},
number={10},
pages={1358-1363},
abstract={The Yasuura method is effective for calculating scattering problems by bodies of revolution. However dealing with 3-D scattering problems, we need to solve bigger size dense matrix equations. One of the methods to solve 3-D scattering is to use multipole expansion which accelerate the convergence rate of solutions on the Yasuura method. We introduce arrays of multipoles and obtain rapidly converging solutions. Therefore we can calculate scattering properties over a relatively wide frequency range and clarify scattering properties such as frequency dependence, shape dependence, and polarization dependence of 3-D scattering from perfectly conducting scatterer. In these numerical results, we keep at least 2 significant figures.},
keywords={},
doi={},
ISSN={},
month={October},}
Copy
TY - JOUR
TI - Numerical Analysis of 3-D Scattering Problems Using the Yasuura Method
T2 - IEICE TRANSACTIONS on Electronics
SP - 1358
EP - 1363
AU - Mitsunori KAWANO
AU - Hiroyoshi IKUNO
AU - Masahiko NISHIMOTO
PY - 1996
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E79-C
IS - 10
JA - IEICE TRANSACTIONS on Electronics
Y1 - October 1996
AB - The Yasuura method is effective for calculating scattering problems by bodies of revolution. However dealing with 3-D scattering problems, we need to solve bigger size dense matrix equations. One of the methods to solve 3-D scattering is to use multipole expansion which accelerate the convergence rate of solutions on the Yasuura method. We introduce arrays of multipoles and obtain rapidly converging solutions. Therefore we can calculate scattering properties over a relatively wide frequency range and clarify scattering properties such as frequency dependence, shape dependence, and polarization dependence of 3-D scattering from perfectly conducting scatterer. In these numerical results, we keep at least 2 significant figures.
ER -
English
