Dispersion characteristics of a rectangular waveguide grating

Author

Maragos, A.A. ; Ioannidis, Z.C. ; Tigelis, I.G.

Author_Institution

Dept. of Phys., Univ. of Athens, Greece

Volume

31

Issue

5

fYear

2003

Firstpage

1075

Lastpage

1082

Abstract

We study the dispersion characteristics of a rectangular waveguide grating for microwave amplifier applications. The Floquet theorem and an appropriate standing waves expansion is employed to express the fields in the vacuum region and inside the grooves, respectively. The application of the boundary conditions leads to an infinite system of equations, which is solved numerically by truncation. The main advantage of the procedure employed is that it gives directly and with a few spatial harmonics the dispersion relation. Furthermore, an adequate procedure (simulation tool) has been introduced in order to distinguish the real roots from spurious solutions and it has been found to work effectively for all cases presented in this work. Numerical results are presented for both shallow and deep grooves and comparison with previously published works is made.

Keywords

diffraction gratings; dispersion (wave); eigenvalues and eigenfunctions; microwave amplifiers; waveguide components; Floquet theorem; boundary conditions; deep grooves; dispersion characteristics; dispersion relation; eigenvalues; grooves; infinite system of equations; microwave amplifier applications; modal analysis; periodic structures; rectangular waveguide grating; shallow grooves; simulation tool; spatial harmonics; spurious solutions; standing waves expansion; truncation; vacuum region; Boundary conditions; Boundary value problems; Eigenvalues and eigenfunctions; Electromagnetic waveguides; Gratings; Integral equations; Microwave generation; Periodic structures; Physics; Rectangular waveguides;

fLanguage

English

Journal_Title

Plasma Science, IEEE Transactions on

Publisher

ieee

ISSN

0093-3813

Type

jour

DOI

10.1109/TPS.2003.819015

Filename

1240060