Symbolic-Numerical Modeling of the Propagation of Adiabatic Waveguide Mode in a Smooth Waveguide Transition

D. V. Divakov; Диваков Д. В.; A. A. Tyutyunnik; Тютюнник А. А.

doi:10.31857/S0044466923010076

Symbolic-Numerical Modeling of the Propagation of Adiabatic Waveguide Mode in a Smooth Waveguide Transition

Authors: Divakov D.V.¹, Tyutyunnik A.A.²
Affiliations:
1. Peoples’ Friendship University of Russia (RUDN University)
2. Joint Institute for Nuclear Research
Issue: Vol 63, No 1 (2023)
Pages: 112-122
Section: УРАВНЕНИЯ В ЧАСТНЫХ ПРОИЗВОДНЫХ
URL: https://journals.rcsi.science/0044-4669/article/view/134293
DOI: https://doi.org/10.31857/S0044466923010076
EDN: https://elibrary.ru/LKQVIF
ID: 134293

Cite item

Full Text

Open Access
Restricted Access

Access granted
Restricted Access

Subscription Access

Abstract
About the authors
References
Supplementary files
Statistics

Abstract

In this work, the model of adiabatic waveguide modes is studied by means of computer algebra. Within the model, the solution of the system of Maxwell’s equations is reduced to a form expressed via the solution of a system of four ordinary differential equations and two algebraic equations for six components of the electromagnetic field. In the case of multilayer waveguides, by means of a computer algebra system, the equations are reduced to a homogeneous system of linear algebraic equations, which is studied symbolically. The condition for non-trivial solvability of the system defines a dispersion relation, which is solved by the symbolic-numerical method, while the system is solved symbolically. The paper presents solutions that describe adiabatic waveguide modes in the zeroth approximation, taking into account the small slope of the interface of the waveguide layer, which are qualitatively different from solutions that do not take into account this slope.

Keywords

symbolic solution of linear equations, symbolic solution of differential equations, adiabatic waveguide modes, guided modes, smoothly irregular waveguide

About the authors

D. V. Divakov

Peoples’ Friendship University of Russia (RUDN University)

Email: divakov-dv@rudn.ru
117198, Moscow, Russia

A. A. Tyutyunnik

Joint Institute for Nuclear Research

Author for correspondence.
Email: tyutyunnik-aa@rudn.ru
141980, Dubna, Moscow oblast, Russia

References

Stevenson A.F. General Theory of Electromagnetic Horns // J. Appl. Phys. 1951. V. 22. № 12. P. 1447.
Schelkunoff S.A. Conversion of Maxwell’s equations into generalized telegraphist’s equations // Bell Syst. Tech. J. 1955. V. 34. P. 995–1043.
Каценеленбаум Б.З. Теория нерегулярных волноводов с медленно меняющимися параметрами. Москва: АН СССР, 1961.
Katsenelenbaum B.Z., Mercader del Rio L., Pereyaslavets M., Sorolla Ayza M., Thumm M. Theory of Nonuniform Waveguides: the cross-section method. The Institution of Engineering and Technology, London, 1998.
Шевченко В.В. Плавные переходы в открытых волноводах: введение в теорию. М.: Наука, 1969.
Свешников А.Г. Приближенный метод расчета слабо нерегулярного волновода // Докл. АН СССР. 1956. Т. 80. № 3. С. 345–347.
Свешников А.Г. К обоснованию методов расчета нерегулярных волноводов // Ж. вычисл. матем. и матем. физ. 1963. Т. 3. № 1. С. 170–179.
Fedoryuk M.V. A justification of the method of transverse sections for an acoustic wave guide with nonhomogeneous content // U.S.S.R. Comput. Math. Math. Phys. 1973. V. 13. № 1. P. 162–173.
Иванов А.А., Шевченко В.В. Плоскопоперечный стык двух планарных волноводов // Радиотехн. и электроника. 2009. Т. 54. № 1. С. 68–77.
Sevastianov L.A., Egorov A.A. Theoretical analysis of the waveguide propagation of electromagnetic waves in dielectric smoothlyirregular integrated structures // Optics and Spectroscopy. 2008. V. 105. № 4. P. 576–584.
Egorov A.A., Sevastianov L.A. Structure of modes of a smoothly irregular integrated optical four-layer three-dimensional waveguide // Quantum Electronics. 2009. V. 39. № 6. P. 566–574.
Egorov A.A., Lovetskiy K.P., Sevastianov A.L., Sevastianov L.A. Simulation of guided modes (eigenmodes) and synthesis of a thin-film generalised waveguide Luneburg lens in the zero-order vector approximation // Quantum Electronics. 2010. V.40. № 9. P. 830–836.
Бабич В.М., Булдырев В.С. Асимптотические методы в задачах дифракции коротких волн. Метод эталонных задач. М.: Наука, 1972.
Divakov D.V., Sevastianov A.L. The Implementation of the Symbolic-Numerical Method for Finding the Adiabatic Waveguide Modes of Integrated Optical Waveguides in CAS Maple // Lecture Notes in Computer Science. 2019. V. 11661. P. 107–121.
Divakov D.V., Tyutyunnik A.A. Symbolic Investigation of the Spectral Characteristics of Guided Modes in Smoothly Irregular Waveguides // Programming and Computer Software. 2022. V. 48. № 2. P. 80–89.
Adams M.J. An Introduction to Optical Waveguides. Wiley, New York, 1981.
Maple homepage, https://www.maplesoft.com/. Last accessed 24 May 2022
Gevorkyan M., Kulyabov D., Lovetskiy K., Sevastianov L., Sevastianov A. Field calculation for the horn waveguide transition in the single-mode approximation of the cross-sections method // Proceedings of SPIE. 2017. V. 10337. P. 103370H.
Divakov D.V., Lovetskiy K.P., Sevastianov L.A., Tiutiunnik A.A. A single-mode model of cross-sectional method in a smoothly irregular transition between planar thin-film dielectric waveguides // Proceedings of SPIE. 2021. V. 11846. P. 118460T.