Solution to the Time-Harmonic Maxwell's Equations in a Waveguide; Use of Higher-Order Derivatives for Solving the Discrete Problem
- 1 August 1997
- journal article
- Published by Society for Industrial & Applied Mathematics (SIAM) in SIAM Journal on Numerical Analysis
- Vol. 34 (4) , 1306-1330
- https://doi.org/10.1137/s0036142994272076
Abstract
The authors study time-harmonic Maxwell's equations in the junction of two rectangular waveguides. They prove existence and uniqueness of the solution, except for a discrete set of values of the frequency of the incident wave. Introducing an artificial boundary condition, they prove that the so-obtained approximate solution converges to the exact solution, and depends analytically on the frequency. They use next higher-order derivatives for solving the approximate problem for a family of shapes of the domain on a large frequency band. This leads to a very efficient method for the numerical simulation of the waveguide, which can be used, for instance, in optimal shape design.Keywords
This publication has 7 references indexed in Scilit:
- Computation of high order derivatives in optimal shape designNumerische Mathematik, 1994
- Integral Equation Methods in a Quasi-Periodic Diffraction Problem for the Time-Harmonic Maxwell’s EquationsSIAM Journal on Mathematical Analysis, 1991
- Numerical solution for exterior problemsNumerische Mathematik, 1987
- Conception optimale ou identification de formes, calcul rapide de la dérivée directionnelle de la fonction coûtESAIM: Mathematical Modelling and Numerical Analysis, 1986
- How to compute fast a function and all its derivativesACM SIGACT News, 1985
- Mixed finite elements in ?3Numerische Mathematik, 1980
- Differentiation with Respect to the Domain in Boundary Value ProblemsNumerical Functional Analysis and Optimization, 1980