Finite element analysis of 2-D dielectric waveguides with Helmholtz vector equations and virtual exterior elements

T. Zheng; N. K. Bao; K. S. Chiang; P. S. Chung

doi:10.1557/PROC-579-281

Finite element analysis of 2-D dielectric waveguides with Helmholtz vector equations and virtual exterior elements

T. Zheng, N. K. Bao, K. S. Chiang, P. S. Chung

Research output: Journal Publications and Reviews › RGC 22 - Publication in policy or professional journal

Abstract

This paper reports a finite-element-method formulation, which is based on the Helmholtz vector equations in terms of transverse electrical field components to characterize two-dimensional dielectric waveguides with an arbitrary continuous permittivity profile. A virtual exterior element iteration technique is associated with the finite-element analysis to process the remote boundary condition. This technique achieves both excellent computational efficiency and accuracy when studying the dielectric propagation constants and cutoff frequencies. The spurious-infection-free modal electrical field can be obtained directly. Numerical results of circular optical fibers with the parabolic permitivity profile are presented to show the validity of this technique.

Original language	English
Pages (from-to)	281-286
Journal	Materials Research Society Symposium - Proceedings
Volume	579
DOIs	https://doi.org/10.1557/PROC-579-281
Publication status	Published - 2000
Externally published	Yes
Event	Optical Properties of Materials - Boston, MA, United States Duration: 30 Nov 1999 → 2 Dec 1999

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title = "Finite element analysis of 2-D dielectric waveguides with Helmholtz vector equations and virtual exterior elements",

abstract = "This paper reports a finite-element-method formulation, which is based on the Helmholtz vector equations in terms of transverse electrical field components to characterize two-dimensional dielectric waveguides with an arbitrary continuous permittivity profile. A virtual exterior element iteration technique is associated with the finite-element analysis to process the remote boundary condition. This technique achieves both excellent computational efficiency and accuracy when studying the dielectric propagation constants and cutoff frequencies. The spurious-infection-free modal electrical field can be obtained directly. Numerical results of circular optical fibers with the parabolic permitivity profile are presented to show the validity of this technique.",

author = "T. Zheng and Bao, {N. K.} and Chiang, {K. S.} and Chung, {P. S.}",

year = "2000",

doi = "10.1557/PROC-579-281",

language = "English",

volume = "579",

pages = "281--286",

journal = "Materials Research Society Symposium - Proceedings",

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note = "Optical Properties of Materials ; Conference date: 30-11-1999 Through 02-12-1999",

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T1 - Finite element analysis of 2-D dielectric waveguides with Helmholtz vector equations and virtual exterior elements

AU - Zheng, T.

AU - Bao, N. K.

AU - Chiang, K. S.

AU - Chung, P. S.

PY - 2000

Y1 - 2000

N2 - This paper reports a finite-element-method formulation, which is based on the Helmholtz vector equations in terms of transverse electrical field components to characterize two-dimensional dielectric waveguides with an arbitrary continuous permittivity profile. A virtual exterior element iteration technique is associated with the finite-element analysis to process the remote boundary condition. This technique achieves both excellent computational efficiency and accuracy when studying the dielectric propagation constants and cutoff frequencies. The spurious-infection-free modal electrical field can be obtained directly. Numerical results of circular optical fibers with the parabolic permitivity profile are presented to show the validity of this technique.

AB - This paper reports a finite-element-method formulation, which is based on the Helmholtz vector equations in terms of transverse electrical field components to characterize two-dimensional dielectric waveguides with an arbitrary continuous permittivity profile. A virtual exterior element iteration technique is associated with the finite-element analysis to process the remote boundary condition. This technique achieves both excellent computational efficiency and accuracy when studying the dielectric propagation constants and cutoff frequencies. The spurious-infection-free modal electrical field can be obtained directly. Numerical results of circular optical fibers with the parabolic permitivity profile are presented to show the validity of this technique.

UR - http://www.scopus.com/inward/record.url?scp=0034447634&partnerID=8YFLogxK

UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-0034447634&origin=recordpage

U2 - 10.1557/PROC-579-281

DO - 10.1557/PROC-579-281

M3 - RGC 22 - Publication in policy or professional journal

SN - 0272-9172

VL - 579

SP - 281

EP - 286

JO - Materials Research Society Symposium - Proceedings

JF - Materials Research Society Symposium - Proceedings

T2 - Optical Properties of Materials

Y2 - 30 November 1999 through 2 December 1999

ER -

Finite element analysis of 2-D dielectric waveguides with Helmholtz vector equations and virtual exterior elements

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