Fourier modal methods for modeling optical dielectric waveguides

J. P. Hugonin; P. Lalanne; Ignacio Del Villar; I. R. Matias

doi:10.1007/s11082-005-1127-2

Fourier modal methods for modeling optical dielectric waveguides

J. P. Hugonin
, P. Lalanne^*
, Ignacio Del Villar
, I. R. Matias

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

46 Citations (Scopus)

Abstract

This work contains new materials relative to the use of Fourier expansion techniques, also called plane-wave expansion techniques, for modelling normal modes of optical waveguides. Two rigorous fully vectorial methods are presented and benchmarked for a classical rib waveguide geometry well studied in the literature. The first method relies on a pole extraction and on a one-dimensional expansion scheme. A four-digit accuracy for the normalized propagation constant B is obtained for the dominant TE and TM modes of the benchmark problem and for a small number of retained Fourier harmonics. Better accuracy is anticipated for larger truncation ranks. The second method relies on a two-dimensional expansion scheme in Fourier space and provides a three-digit accuracy for the normalized propagation constant.

Original language	English
Pages (from-to)	107-119
Number of pages	13
Journal	Optical and Quantum Electronics
Volume	37
Issue number	1-3
DOIs	https://doi.org/10.1007/s11082-005-1127-2
Publication status	Published - 2005
Externally published	Yes

Keywords

Electromagnetic theory
Fourier expansion techniques
Optical mode solver

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10.1007/s11082-005-1127-2

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title = "Fourier modal methods for modeling optical dielectric waveguides",

abstract = "This work contains new materials relative to the use of Fourier expansion techniques, also called plane-wave expansion techniques, for modelling normal modes of optical waveguides. Two rigorous fully vectorial methods are presented and benchmarked for a classical rib waveguide geometry well studied in the literature. The first method relies on a pole extraction and on a one-dimensional expansion scheme. A four-digit accuracy for the normalized propagation constant B is obtained for the dominant TE and TM modes of the benchmark problem and for a small number of retained Fourier harmonics. Better accuracy is anticipated for larger truncation ranks. The second method relies on a two-dimensional expansion scheme in Fourier space and provides a three-digit accuracy for the normalized propagation constant.",

keywords = "Electromagnetic theory, Fourier expansion techniques, Optical mode solver",

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AU - Hugonin, J. P.

AU - Lalanne, P.

AU - Del Villar, Ignacio

AU - Matias, I. R.

PY - 2005

Y1 - 2005

N2 - This work contains new materials relative to the use of Fourier expansion techniques, also called plane-wave expansion techniques, for modelling normal modes of optical waveguides. Two rigorous fully vectorial methods are presented and benchmarked for a classical rib waveguide geometry well studied in the literature. The first method relies on a pole extraction and on a one-dimensional expansion scheme. A four-digit accuracy for the normalized propagation constant B is obtained for the dominant TE and TM modes of the benchmark problem and for a small number of retained Fourier harmonics. Better accuracy is anticipated for larger truncation ranks. The second method relies on a two-dimensional expansion scheme in Fourier space and provides a three-digit accuracy for the normalized propagation constant.

AB - This work contains new materials relative to the use of Fourier expansion techniques, also called plane-wave expansion techniques, for modelling normal modes of optical waveguides. Two rigorous fully vectorial methods are presented and benchmarked for a classical rib waveguide geometry well studied in the literature. The first method relies on a pole extraction and on a one-dimensional expansion scheme. A four-digit accuracy for the normalized propagation constant B is obtained for the dominant TE and TM modes of the benchmark problem and for a small number of retained Fourier harmonics. Better accuracy is anticipated for larger truncation ranks. The second method relies on a two-dimensional expansion scheme in Fourier space and provides a three-digit accuracy for the normalized propagation constant.

KW - Electromagnetic theory

KW - Fourier expansion techniques

KW - Optical mode solver

UR - https://www.scopus.com/pages/publications/21344443955

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DO - 10.1007/s11082-005-1127-2

M3 - Article

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VL - 37

SP - 107

EP - 119

JO - Optical and Quantum Electronics

JF - Optical and Quantum Electronics

IS - 1-3

ER -

Fourier modal methods for modeling optical dielectric waveguides

Abstract

Keywords

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