A finite-element-based vectorial optical mode solver is used to analyze microstructured optical waveguides. By employing 1st-order Bayliss-Gunzburger-Turkel-like transparent boundary conditions, both the real and imaginary part of the modal indices can be calculated in a relatively small computational domain. Results for waveguides with either circular or non-circular microstructured holes, solid- or air-core will be presented, including the silica-air Bragg fiber recently demonstrated by Vienne et al. (Post-deadline Paper PDP25, OFC 2004). The results of solid-core structures are in good agreement with the results of other methods while the results of air-core structure agree to the experimental results.
Description
Optics InfoBase: Optics Express - Modelling of microstructured waveguides using a finite-element-based vectorial mode solver with transparent boundary conditions
%0 Journal Article
%1 Uranus:04
%A Uranus, Henri
%A Hoekstra, H.
%D 2004
%I OSA
%J Opt. Express
%K element finite microstructured modelling waveguides
%N 12
%P 2795--2809
%T Modelling of microstructured waveguides using a finite-element-based vectorial mode solver with transparent boundary conditions
%U http://www.opticsexpress.org/abstract.cfm?URI=oe-12-12-2795
%V 12
%X A finite-element-based vectorial optical mode solver is used to analyze microstructured optical waveguides. By employing 1st-order Bayliss-Gunzburger-Turkel-like transparent boundary conditions, both the real and imaginary part of the modal indices can be calculated in a relatively small computational domain. Results for waveguides with either circular or non-circular microstructured holes, solid- or air-core will be presented, including the silica-air Bragg fiber recently demonstrated by Vienne et al. (Post-deadline Paper PDP25, OFC 2004). The results of solid-core structures are in good agreement with the results of other methods while the results of air-core structure agree to the experimental results.
@article{Uranus:04,
abstract = {A finite-element-based vectorial optical mode solver is used to analyze microstructured optical waveguides. By employing 1st-order Bayliss-Gunzburger-Turkel-like transparent boundary conditions, both the real and imaginary part of the modal indices can be calculated in a relatively small computational domain. Results for waveguides with either circular or non-circular microstructured holes, solid- or air-core will be presented, including the silica-air Bragg fiber recently demonstrated by Vienne et al. (Post-deadline Paper PDP25, OFC 2004). The results of solid-core structures are in good agreement with the results of other methods while the results of air-core structure agree to the experimental results.},
added-at = {2009-05-16T09:01:13.000+0200},
author = {Uranus, Henri and Hoekstra, H.},
biburl = {https://www.bibsonomy.org/bibtex/208694acc0e19aa77213f973616da52ad/krisrowland},
description = {Optics InfoBase: Optics Express - Modelling of microstructured waveguides using a finite-element-based vectorial mode solver with transparent boundary conditions},
interhash = {3be551c283ede15f933a84a8d1b72012},
intrahash = {08694acc0e19aa77213f973616da52ad},
journal = {Opt. Express},
keywords = {element finite microstructured modelling waveguides},
number = 12,
pages = {2795--2809},
publisher = {OSA},
timestamp = {2009-05-16T09:01:13.000+0200},
title = {Modelling of microstructured waveguides using a finite-element-based vectorial mode solver with transparent boundary conditions},
url = {http://www.opticsexpress.org/abstract.cfm?URI=oe-12-12-2795},
volume = 12,
year = 2004
}