Title :
A Fast and Stabilized Method for Gratings
Author :
Tian-Lin Dong ; Boyuan Chen ; Lin Li ; Qi Huang ; Jin Li ; Qingxia Li ; Ping Chen
Author_Institution :
Dept. of Electron. & Inf., Huazhong Univ. of Sci. & Technol., Wuhan, China
Abstract :
The widely used Rayleigh expansion is not generally bounded and causes the instability and some limitations in numerical process. We extend the radiation condition for diffraction grating problems and stress that the radiation field excited by a planar periodic current source satisfies the generalized radiation condition; hence, it can be used as a modified Rayleigh expansion to formulate an enhanced Rayleigh method. The proposed method can considerably extend the domain of validity. Invoking the internal regularization mechanism, it can work with success when amplitude/period ratio equals 0.5 or higher for a sinusoidal metal grating and s polarization with normal incidence. At the same time, the simplicity, efficiency, and ability to explicitly depict the interactions among diffracted orders are as good as, if not better than in the Rayleigh method.
Keywords :
diffraction gratings; light polarisation; numerical stability; amplitude/period ratio; diffracted orders; diffraction grating problems; efficiency; enhanced Rayleigh method; fast method; generalized radiation condition; instability; internal regularization mechanism; modified Rayleigh expansion; normal incidence; numerical process; planar periodic current source; radiation field; s polarization; simplicity; sinusoidal metal grating; stabilized method; Boundary conditions; Computers; Diffraction; Diffraction gratings; Equations; Gratings; Optical surface waves; Corrugated surfaces; Gratings; Numerical stability; Optical diffraction; corrugated surfaces; gratings; numerical stability;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2370050
