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.
© 2012 IEEE
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