DocumentCode
991986
Title
Optimum scattering from an array of half-wave dipoles
Author
Coe, Richard J. ; Ishimaru, Akira
Author_Institution
Aerospace Group, Boeing Company, Seattle, WA, USA
Volume
18
Issue
2
fYear
1970
fDate
3/1/1970 12:00:00 AM
Firstpage
224
Lastpage
230
Abstract
Optimization of the field scattered by an antenna has important applications in radar systems and as elements in passive communication links. A method is presented of optimizing the scattering from a linear array of half-wavelength dipoles at a prescribed bistatic angle. The array is excited by a plane wave incident at an arbitrarily specified angle. The field scattered by the array is maximized or minimized as a function of the parameters of a network connected to the accessible antenna terminals. The result is a matrix eigenvalue equation of order
for the optimum parameters of an
-element array. It is known that
solutions of this equation exist, which yield a prescribed zero in the bistatic scattering pattern but they do not correspond to physical networks. Using linear combinations of these, we construct a family of optimum admittance matrices that satisfy necessary and sufficient conditions that they be admittance matrices of passive networks. The form of the matrices is such that the corresponding passive regions in the bistatic plane are easily determined. The corresponding network can then be realized using existing network synthesis procedures. The essential features of the theory are illustrated by synthesizing an optimum network for a two-element array. It is also shown that backscatter at any angle can be minimized independently of the receiving pattern of the array.
for the optimum parameters of an
-element array. It is known that
solutions of this equation exist, which yield a prescribed zero in the bistatic scattering pattern but they do not correspond to physical networks. Using linear combinations of these, we construct a family of optimum admittance matrices that satisfy necessary and sufficient conditions that they be admittance matrices of passive networks. The form of the matrices is such that the corresponding passive regions in the bistatic plane are easily determined. The corresponding network can then be realized using existing network synthesis procedures. The essential features of the theory are illustrated by synthesizing an optimum network for a two-element array. It is also shown that backscatter at any angle can be minimized independently of the receiving pattern of the array.Keywords
Dipole arrays; Electromagnetic (EM) scattering; Loaded antennas; Admittance; Dipole antennas; Equations; Linear antenna arrays; Network synthesis; Optimization methods; Passive radar; Radar antennas; Radar applications; Radar scattering;
fLanguage
English
Journal_Title
Antennas and Propagation, IEEE Transactions on
Publisher
ieee
ISSN
0018-926X
Type
jour
DOI
10.1109/TAP.1970.1139651
Filename
1139651
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