An Asymptotic Solution for Boundary - Layer Fields Near a Convex Impedance Surface

-An analytic representation for fields (E, H) that, for wavenumber k, satisfies the Maxwell equations to order k -2/3 within a suitably-defined boundary-layer neighborhood is provided for the case of a general doubly-curved convex impedance surface. This solution is an ansatz construct obtained via...

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Bibliographic Details
Published inJournal of electromagnetic waves and applications Vol. 16; no. 2; pp. 185 - 208
Main Authors Hussar, P.E., Smith-Rowland, E.M.
Format Journal Article
LanguageEnglish
Published Zeist Taylor & Francis Group 01.01.2002
VSP
Subjects
Applied sciences
Exact sciences and technology
Radiocommunications
Radiowave propagation
Telecommunications
Telecommunications and information theory
Electromagnetic field
Convex surface
Maxwell equation
Analytic representation
Heuristic method
Boundary layer
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Summary:-An analytic representation for fields (E, H) that, for wavenumber k, satisfies the Maxwell equations to order k -2/3 within a suitably-defined boundary-layer neighborhood is provided for the case of a general doubly-curved convex impedance surface. This solution is an ansatz construct obtained via heuristic modification of a residue-series solution to a corresponding circular-cylinder canonical problem with an infinitesimal axial magnetic dipole excitation. The field components are in the form of creeping-ray modal series written as functions of geodesic-polar and normal coordinates (s, , n) appropriate to the vicinity of a general convex surface. Adaptation of the canonical solution to the general case begins with a transformation from the native cylindrical (p, φ, z) coordinates of the canonical solution to a system ( p, c , s) defined by cylinder-surface geodesics. The transformed canonical solution is further modified by replacement of corresponding factors deriving from the metric and curl operators in the (p, c , s) and (s, , n) systems, and by pervasive application of a substitution previously employed in a more limited way by Pathak and Wang. The physical content of the substitution process is that the creeping-ray attenuation along the geodesics occurs independently of the surface normal curvature transverse to the geodesic direction.
ISSN:0920-5071
1569-3937
DOI:10.1163/156939302X00831