Optimal far-field focusing of uniformly spaced arrays subject to arbitrary upper bounds in nontarget directions
Articolo
Data di Pubblicazione:
2002
Abstract:
A new approach providing new theoretical results to the optimal far-field
focusing of uniformly spaced arrays, subject to a completely arbitrary mask
for sidelobe bounds, is presented and discussed. In both cases of linear or
planar arrays (with rectangular boundaries), it is first shown that the
problem can be formulated, without any loss to performances on the maximum,
as a linear programming one, guaranteeing a globally optimal solution.
Second, a sufficient uniqueness criterion for the solution of the overall
problem is also developed, which shows how the solution may not be unique
(as is actually the case) when planar arrays are considered. In addition,
further globally effective optimization procedures are proposed for the
latter case in order to optimize directivity, smoothness of excitations, or
other performance parameters in the set of equivalent solutions. Last, an
extension to planar arrays with a nonrectangular boundary is also given. A
thorough numerical analysis confirms the effectiveness of the approach
proposed and of the solution codes developed.
focusing of uniformly spaced arrays, subject to a completely arbitrary mask
for sidelobe bounds, is presented and discussed. In both cases of linear or
planar arrays (with rectangular boundaries), it is first shown that the
problem can be formulated, without any loss to performances on the maximum,
as a linear programming one, guaranteeing a globally optimal solution.
Second, a sufficient uniqueness criterion for the solution of the overall
problem is also developed, which shows how the solution may not be unique
(as is actually the case) when planar arrays are considered. In addition,
further globally effective optimization procedures are proposed for the
latter case in order to optimize directivity, smoothness of excitations, or
other performance parameters in the set of equivalent solutions. Last, an
extension to planar arrays with a nonrectangular boundary is also given. A
thorough numerical analysis confirms the effectiveness of the approach
proposed and of the solution codes developed.
Tipologia CRIS:
01.01 Articolo in rivista
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