This paper shows the applicability of the integral equation formulation of the measured equation of invariance (IE-MEI) to two-dimensional dielectric scatterers. That is, a relationship between the scattered electric and magnetic fields, which is derived from the new formulation of the IE-MEI, is applicable to lossless dielectric materials as well as perfect electric conductors (PEC). In addition, we show that the IE-MEI does not suffer from internal resonance problems. These two facts are validated by numerical examples for a circular cylinder and a square cylinder illuminated by Transverse Magnetic (TM) plane wave or a TM line source very close to the scatterers. The numerical results calculated by the IE-MEI agree well with the ones by moment methods that employ combined field formulations with exact boundary conditions.
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Masanobu HIROSE, Masayasu MIYAKE, Jun-ichi TAKADA, Ikuo ARAI, "On Applicability of the Integral Equation Formulation of the Measured Equation of Invariance to 2D Scattering Objects" in IEICE TRANSACTIONS on Communications,
vol. E82-B, no. 4, pp. 645-654, April 1999, doi: .
Abstract: This paper shows the applicability of the integral equation formulation of the measured equation of invariance (IE-MEI) to two-dimensional dielectric scatterers. That is, a relationship between the scattered electric and magnetic fields, which is derived from the new formulation of the IE-MEI, is applicable to lossless dielectric materials as well as perfect electric conductors (PEC). In addition, we show that the IE-MEI does not suffer from internal resonance problems. These two facts are validated by numerical examples for a circular cylinder and a square cylinder illuminated by Transverse Magnetic (TM) plane wave or a TM line source very close to the scatterers. The numerical results calculated by the IE-MEI agree well with the ones by moment methods that employ combined field formulations with exact boundary conditions.
URL: https://global.ieice.org/en_transactions/communications/10.1587/e82-b_4_645/_p
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@ARTICLE{e82-b_4_645,
author={Masanobu HIROSE, Masayasu MIYAKE, Jun-ichi TAKADA, Ikuo ARAI, },
journal={IEICE TRANSACTIONS on Communications},
title={On Applicability of the Integral Equation Formulation of the Measured Equation of Invariance to 2D Scattering Objects},
year={1999},
volume={E82-B},
number={4},
pages={645-654},
abstract={This paper shows the applicability of the integral equation formulation of the measured equation of invariance (IE-MEI) to two-dimensional dielectric scatterers. That is, a relationship between the scattered electric and magnetic fields, which is derived from the new formulation of the IE-MEI, is applicable to lossless dielectric materials as well as perfect electric conductors (PEC). In addition, we show that the IE-MEI does not suffer from internal resonance problems. These two facts are validated by numerical examples for a circular cylinder and a square cylinder illuminated by Transverse Magnetic (TM) plane wave or a TM line source very close to the scatterers. The numerical results calculated by the IE-MEI agree well with the ones by moment methods that employ combined field formulations with exact boundary conditions.},
keywords={},
doi={},
ISSN={},
month={April},}
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TY - JOUR
TI - On Applicability of the Integral Equation Formulation of the Measured Equation of Invariance to 2D Scattering Objects
T2 - IEICE TRANSACTIONS on Communications
SP - 645
EP - 654
AU - Masanobu HIROSE
AU - Masayasu MIYAKE
AU - Jun-ichi TAKADA
AU - Ikuo ARAI
PY - 1999
DO -
JO - IEICE TRANSACTIONS on Communications
SN -
VL - E82-B
IS - 4
JA - IEICE TRANSACTIONS on Communications
Y1 - April 1999
AB - This paper shows the applicability of the integral equation formulation of the measured equation of invariance (IE-MEI) to two-dimensional dielectric scatterers. That is, a relationship between the scattered electric and magnetic fields, which is derived from the new formulation of the IE-MEI, is applicable to lossless dielectric materials as well as perfect electric conductors (PEC). In addition, we show that the IE-MEI does not suffer from internal resonance problems. These two facts are validated by numerical examples for a circular cylinder and a square cylinder illuminated by Transverse Magnetic (TM) plane wave or a TM line source very close to the scatterers. The numerical results calculated by the IE-MEI agree well with the ones by moment methods that employ combined field formulations with exact boundary conditions.
ER -