DocumentCode
1759227
Title
Numerical Methods for Calculating Poles of the Scattering Matrix With Applications in Grating Theory
Author
Bykov, D.A. ; Doskolovich, L.L.
Author_Institution
Image Process. Syst. Inst., Samara, Russia
Volume
31
Issue
5
fYear
2013
fDate
41334
Firstpage
793
Lastpage
801
Abstract
Waveguide and resonant properties of diffractive structures are often explained through the complex poles of their scattering matrices. Numerical methods for calculating poles of the scattering matrix with applications in grating theory are discussed and analyzed. A new iterative method for computing the scattering matrix poles is proposed. The method takes account of the scattering matrix form in the pole vicinity and relies upon solving matrix equations with use of matrix decompositions. Using the same mathematical approach, we also describe a Cauchy-integral-based method that allows all of the poles in a specified domain to be calculated. Calculation of the modes of a metal-dielectric diffraction grating shows that the iterative method proposed has the high rate of convergence and is numerically stable for large-dimension scattering matrices. An important advantage of the proposed method is that it usually converges to the nearest pole.
Keywords
S-matrix theory; diffraction gratings; iterative methods; optical design techniques; optical waveguide theory; Cauchy integral based method; diffractive structures; grating theory; iterative method; optical waveguide; pole calculation; resonant properties; scattering matrix; Diffraction; Diffraction gratings; Eigenvalues and eigenfunctions; Iterative methods; Matrix decomposition; Scattering; Transmission line matrix methods; Diffraction grating; optical resonance; quasi-guided eigenmode; scattering matrix pole;
fLanguage
English
Journal_Title
Lightwave Technology, Journal of
Publisher
ieee
ISSN
0733-8724
Type
jour
DOI
10.1109/JLT.2012.2234723
Filename
6384630
Link To Document