Mode reduction for efficient modeling of photonic crystal slab structures

Lijun Yuan; Ya Yan Lu

doi:10.1109/JLT.2014.2324020

Mode reduction for efficient modeling of photonic crystal slab structures

Lijun Yuan, Ya Yan Lu

Department of Mathematics

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

Rigorous numerical simulations for photonic crystal (PhC) slab structures and devices are difficult due to the complicated three-dimensional (3-D) geometry, high index-contrast, sharp edges, and possibly inhomogeneity at infinity. The approach based on expanding the field in 1-D vertical modes has great potential, but is currently limited by the relatively large number of modes needed for maintaining the accuracy of the solutions. In this paper, we show that if a single hole is first analyzed with the full set of vertical modes, the number of modes can be reduced to less than one third of the total in the main part of the computation. This leads to a speedup of more than 27 times. The method is illustrated by computing the transmission and reflection spectra for a PhC slab with a finite number of hole arrays. © 2014 IEEE.

Original language	English
Article number	6815961
Pages (from-to)	2340-2344
Journal	Journal of Lightwave Technology
Volume	32
Issue number	13
Online published	15 May 2014
DOIs	https://doi.org/10.1109/JLT.2014.2324020
Publication status	Published - 1 Jul 2014

Research Keywords

Mode matching methods
modeling
periodic structures
photonic crystals

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title = "Mode reduction for efficient modeling of photonic crystal slab structures",

abstract = "Rigorous numerical simulations for photonic crystal (PhC) slab structures and devices are difficult due to the complicated three-dimensional (3-D) geometry, high index-contrast, sharp edges, and possibly inhomogeneity at infinity. The approach based on expanding the field in 1-D vertical modes has great potential, but is currently limited by the relatively large number of modes needed for maintaining the accuracy of the solutions. In this paper, we show that if a single hole is first analyzed with the full set of vertical modes, the number of modes can be reduced to less than one third of the total in the main part of the computation. This leads to a speedup of more than 27 times. The method is illustrated by computing the transmission and reflection spectra for a PhC slab with a finite number of hole arrays. {\textcopyright} 2014 IEEE.",

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T1 - Mode reduction for efficient modeling of photonic crystal slab structures

AU - Yuan, Lijun

AU - Lu, Ya Yan

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N2 - Rigorous numerical simulations for photonic crystal (PhC) slab structures and devices are difficult due to the complicated three-dimensional (3-D) geometry, high index-contrast, sharp edges, and possibly inhomogeneity at infinity. The approach based on expanding the field in 1-D vertical modes has great potential, but is currently limited by the relatively large number of modes needed for maintaining the accuracy of the solutions. In this paper, we show that if a single hole is first analyzed with the full set of vertical modes, the number of modes can be reduced to less than one third of the total in the main part of the computation. This leads to a speedup of more than 27 times. The method is illustrated by computing the transmission and reflection spectra for a PhC slab with a finite number of hole arrays. © 2014 IEEE.

AB - Rigorous numerical simulations for photonic crystal (PhC) slab structures and devices are difficult due to the complicated three-dimensional (3-D) geometry, high index-contrast, sharp edges, and possibly inhomogeneity at infinity. The approach based on expanding the field in 1-D vertical modes has great potential, but is currently limited by the relatively large number of modes needed for maintaining the accuracy of the solutions. In this paper, we show that if a single hole is first analyzed with the full set of vertical modes, the number of modes can be reduced to less than one third of the total in the main part of the computation. This leads to a speedup of more than 27 times. The method is illustrated by computing the transmission and reflection spectra for a PhC slab with a finite number of hole arrays. © 2014 IEEE.

KW - Mode matching methods

KW - modeling

KW - periodic structures

KW - photonic crystals

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DO - 10.1109/JLT.2014.2324020

M3 - RGC 21 - Publication in refereed journal

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EP - 2344

JO - Journal of Lightwave Technology

JF - Journal of Lightwave Technology

IS - 13

M1 - 6815961

ER -

Mode reduction for efficient modeling of photonic crystal slab structures

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