Maximally Sparse Arrays Via Sequential Convex Optimizations

The design of sparse arrays able to radiate focused beam patterns satisfying a given upper-bound power mask with the minimum number of sources is a research area of increasing interest. The related synthesis problem can be formulated with proper constraints on the cardinality of the solution space,...

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Bibliographic Details
Published in:IEEE antennas and wireless propagation letters 2012, Vol.11, p.192-195
Main Authors: Prisco, G., D'Urso, M.
Format: Article
Language:English
Subjects:
Antenna arrays
Apertures
Compressed sensing
Convex functions
global optimizations
Minimization
Optimization
Sensor arrays
sequential convex optimization
sparse array
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Summary:The design of sparse arrays able to radiate focused beam patterns satisfying a given upper-bound power mask with the minimum number of sources is a research area of increasing interest. The related synthesis problem can be formulated with proper constraints on the cardinality of the solution space, i.e., its l 0 -norm. Unfortunately, such a nonconvex constraint requires to solve an NP-hard problem. Interesting ideas to relax the above constraint in a convex way have been successfully proposed. A possible solution is based on the minimization of the l 1 -norm. This strategy is not always able to achieve a maximally sparse solution. In the following, an innovative synthesis scheme that optimizes both excitation weights and sensor positions of an array radiating pencil beam-patterns is discussed. The solution algorithm is based on sequential convex optimizations including a reweighted l 1 -norm minimization. Numerical tests, referred to benchmark problems, show that the proposed synthesis method is able to achieve maximally sparse linear arrays, also compared to the best results reported in the literature, obtained by means of global optimization schemes.
ISSN:1536-1225
1548-5757
DOI:10.1109/LAWP.2012.2186626