An Efficient Rescaled Formulation for Tensor Green’s Function Computation in Cylindrical Multilayered Media

Author

Guanglong Xing ; Teixeira, Fernando L.

Author_Institution

Coll. of Inf. Sci. & Eng., YanShan Univ., Qinhuangdao, China

Volume

63

Issue

12

fYear

2015

Firstpage

5677

Lastpage

5685

Abstract

A robust formulation is presented to eliminate overflow, underflow, and convergence problems that arise the computation of tensor Green´s functions in cylindrical multilayered media under finite-precision arithmetic. This is done by first introducing a set of rescaled functions associated to the (canonical) cylindrical Bessel and Hankel functions representing standing waves and outgoing waves along the radial direction. The rescaled cylindrical functions are designed to avoid the poor scaling inherent to the canonical cylindrical functions for very small or very large arguments. In addition, a parabolic Sommerfeld integration path is constructed in the spectral complex plane to yield a numerical integration with good convergence properties for a wide range of parameter values.

Keywords

Hankel matrices; numerical analysis; tensors; Hankel functions; canonical cylindrical Bessel; cylindrical multilayered media; finite precision arithmetic; numerical integration; radial direction; rescaled cylindrical functions; rescaled formulation; rescaled functions; robust formulation; spectral complex plane; tensor green function computation; Antennas; Convergence; Eigenvalues and eigenfunctions; Green´s function methods; Media; Robustness; Tensile stress; Borehole exploration; Green’s function; Green???s function; borehole exploration; cylindrical eigenfunctions; multilayered media;

fLanguage

English

Journal_Title

Antennas and Propagation, IEEE Transactions on

Publisher

ieee

ISSN

0018-926X

Type

jour

DOI

10.1109/TAP.2015.2490740

Filename

7298425