AN EFFICIENT METHOD FOR THE COMPUTATION OF MIXED POTENTIAL GREEN'S FUNCTIONS IN CYLINDRICALLY STRATIFIED MEDIA

Closed-form mixed potential Green's functions (MPGFs) for cylindrically stratified media are derived in terms of quasistatic-wave and surface-wave contributions. In order to avoid possible overflow/underflow problems in the numerical calculations of special cylindrical functions such as Bessel...

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Bibliographic Details
Published in:Electromagnetic waves (Cambridge, Mass.) Mass.), 2012-03, Vol.125, p.37-53
Main Authors: Ye, L.F, Xiao, K, Qiu, L, Chai, S.L, Mao, J.J
Format: Article
Language:English
Subjects:
Electric waves
Electromagnetic radiation
Electromagnetic waves
Engineering research
Potential theory (Mathematics)
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Summary:Closed-form mixed potential Green's functions (MPGFs) for cylindrically stratified media are derived in terms of quasistatic-wave and surface-wave contributions. In order to avoid possible overflow/underflow problems in the numerical calculations of special cylindrical functions such as Bessel and Hankel functions, a novel form of the spectral-domain MPGFs is developed. Then, a two-level methodology is used for the approximation of the spectral-domain MPGFs. In the first step, the qusistatic components are extracted from the spectral-domain MPGFs, and then transformed into the space domain with the use of the Sommerfeld identity and its derivatives. In the second step, the remaining parts of the spectral-domain MPGFs are approximated in terms of pole-residue expressions via the rational function fitting method (RFFM). The proposed method is efficient and fully automatic, which avoids an analytical cumbersome extraction of the surface wave poles (SWPs), prior to the spectrum fitting. In addition, this method can evaluate the spatial-domain MPGFs accurately and efficiently for both the near-and far-fields. Finally, numerical results for the spatial-domain MPGFs of a two-layer structure are presented and discussed.
ISSN:1559-8985
1070-4698
1559-8985
DOI:10.2528/PIER11112311