Modal bases of coaxial electromagnetic step index fibers
Abstract
We consider the eigenvalue problem to find the modes of an electromagnetic coaxial step index fiber. More specific, we consider a closed (meaning PEC boundary conditions) cylindrical waveguide with circular cross section , wave propagation modeled by the time-harmonic Maxwell's equations with frequency ω, the permeability μ and the permittivity ε being scalar, uniformly positive, piece-wise constant and depending only on the radial variable of the cross section. We prove that if the deviation from the homogeneous case is small, i.e., δε,μ:=\|ε-ε0\|L∞+\|μ-μ0\|L∞1, then the tangential electric (magnetic) fields of the modes form a Riesz basis in H0(curl;) (H(curl;)). For a constant permeability (permittivity) the Riesz basis property for the tangential electric (magnetic) fields holds also in the natural trace space H0-1/2(curl;) (H-1/2(curl;)). These results hold also for complex frequencies ω. In addition, if ω∈R, then for small enough δε,μ all wavenumbers are located on the axes and there exist no backward modes. Key tools in the analysis are a particular reformulation of the eigenvalue problem, the perturbation theory for selfadjoint operators under a local subordinate condition and uniform properties of Bessel functions.
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