Toru Eizawa scite author profile

Abstract-The diffraction by a finite sinusoidal grating is analyzed for the H-polarized plane wave incidence using the Wiener-Hopf technique combined with the perturbation method. Assuming the depth of the grating to be small compared with the wavelength and approximating the boundary condition on the grating surface, the problem is reduced to the diffraction problem involving a flat strip with a certain mixed boundary condition. Introducing the Fourier transform for the unknown scattered field and applying an approximate boundary condition together with a perturbation series expansion for the scattered field, the problem is formulated in terms of the zero-order and first-order Wiener-Hopf equations. The Wiener-Hopf equations are solved via the factorization and decomposition procedure leading to the exact and asymptotic solutions. Taking the inverse Fourier transform and applying the saddle point method, the scattered field expression is explicitly derived. Scattering characteristics of the grating are discussed in detail via numerical examples of the far field intensity.

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Wiener-Hopf Analysis of the High-Frequency Diffraction by a Strip

Koshikawa

Kobayashi

Eizawa³

1993

IEEJ Trans. FM

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Plane Wave Diffraction by a Finite Parallel-Plate Waveguide With Sinusoidal Wall Corrugation

Eizawa¹,

Kobayashi²

2017

PIER B

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Abstract-The diffraction by a finite parallel-plate waveguide with sinusoidal wall corrugation is analyzed for the E-polarized plane wave incidence using the Wiener-Hopf technique combined with the perturbation method. Assuming that the corrugation amplitude of the waveguide walls is small compared with the wavelength and expanding the boundary condition on the waveguide surface into the Taylor series, the problem is reduced to the diffraction by a flat, finite parallel-plate waveguide with a certain mixed boundary condition. Introducing the Fourier transform for the unknown scattered field and applying an approximate boundary condition together with a perturbation series expansion for the scattered field, the problem is formulated in terms of the zero-order and the first-order Wiener-Hopf equations. The Wiener-Hopf equations are solved via the factorization and decomposition procedure leading to the exact and asymptotic solutions. Taking the inverse Fourier transform and applying the saddle point method, a scattered far field expression is derived explicitly. Scattering characteristics of the waveguide are discussed in detail via numerical examples of the radar cross section (RCS).

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Wiener-Hopf analysis of the diffraction by a finite sinusoidal grating

Eizawa¹,

Kobayashi

2017

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Toru Eizawa

Full wave analysis of plane wave diffraction by a finite sinusoidal grating: E-polarization case

WIENER-HOPF ANALYSIS OF THE H-POLARIZED PLANE WAVE DIFFRACTION BY A FINITE SINUSOIDAL GRATING (Invited Paper)

Wiener-Hopf Analysis of the High-Frequency Diffraction by a Strip

Plane Wave Diffraction by a Finite Parallel-Plate Waveguide With Sinusoidal Wall Corrugation

Wiener-Hopf analysis of the diffraction by a finite sinusoidal grating

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