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Generalised approach to modelling shielded printed-circuit transmission lines

Generalised approach to modelling shielded printed-circuit transmission lines

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A new generalised approach for the full-wave analysis of shielded printed-circuit transmission lines with finite metallisation thickness is presented. A rigorous formulation for the electric field vector is employed, representing the hybrid electromagnetic field in layers of multidielectric media. The dyadic Green's function of the electric kind is derived as a kernel of the vector integral representations for the electric field. Based on the method of overlapping regions, the approach can be applied to the characterisation of a large class of planar waveguiding structures to yield a set of linear algebraic equations of the second kind with a compact matrix operator. Numerical examples are shown for single and coupled shielded planar transmission lines illustrating application of the method. The technique described allows obtaining accurate and mathematically correct solutions of planar waveguide eigenvalue problems.

Inspec keywords: Green's function methods; planar waveguides; convergence of numerical methods; boundary integral equations; matrix algebra; printed circuits; eigenvalues and eigenfunctions; microstrip lines; waveguide theory; electromagnetic shielding

Other keywords: vector integral representations; dyadic Green's function; planar waveguide eigenvalue problems; linear algebraic equations; shielded printed-circuit transmission lines; finite metallisation thickness; coupled shielded planar transmission lines; full-wave analysis; overlapping regions; planar waveguide structures; single shielded planar transmission lines; hybrid electromagnetic field; electric field vector; multidielectric media; compact matrix operator

Subjects: Integral equations (numerical analysis); Printed circuits; Waveguide and cavity theory; Waveguides and microwave transmission lines; Linear algebra (numerical analysis)

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