Title :
A Fourier-Fresnel integral-based transfer function model for a near-parabolic phase profile arrayed-waveguide grating
Author :
Parker, Michael C. ; Walker, Stuart D.
Author_Institution :
Fujitsu Telecomm. Eur. Ltd. Res., Colchester, UK
Abstract :
The near-parabolic phase profile arrayed-waveguide grating (AWG) is known to exhibit a broad yet flat passband response. However, to our knowledge, the near-parabolic phase profile solution was previously obtainable only by numerical methods. Here, we show how a novel, hidden-variable optimization of an even second-order approximation to the near-parabolic phase aperture function, allows the AWG spectral transfer function to be described using a Fourier-Fresnel transform. The Fresnel integral-based analytic expression obtained provides a good fit to within 2.15 dB across the 3-dB passband width compared with the exact solution.
Keywords :
Fourier transform optics; diffraction gratings; integral equations; integrated optics; optical arrays; optical transfer function; optical waveguide theory; optimisation; AWG spectral transfer function; Fourier-Fresnel integral-based transfer function model; Fourier-Fresnel transform; Fresnel integral-based analytic expression; exact solution; flat passband response; hidden-variable optimization; near-parabolic phase aperture function; near-parabolic phase profile arrayed-waveguide grating; near-parabolic phase profile solution; second-order approximation; Apertures; Arrayed waveguide gratings; Fourier transforms; Integrated optics; Optical devices; Optical filters; Optical waveguides; Passband; Phased arrays; Transfer functions;
Journal_Title :
Photonics Technology Letters, IEEE
