DocumentCode
1349923
Title
Implementation and convergence considerations of a linearly constrained adaptive array
Author
Gerlach, Karl
Author_Institution
US Naval Res. Lab., Washington, DC, USA
Volume
26
Issue
2
fYear
1990
fDate
3/1/1990 12:00:00 AM
Firstpage
263
Lastpage
272
Abstract
O.L. Frost (1972) introduced a linearly constrained optimization algorithm that allows certain main beam properties to be preserved while good cancellation is attained. An open-loop implementation of this algorithm is developed. This implementation is shown to be equivalent to the technique developed by C.W. Jim (1977), L.J. Griffiths and C.W. Jin (1982), and K.M. Buckley and L.J. Griffiths (1982) whereby the constrained problem is reduced to an unconstrained problem. Analytical results are presented for the convergence rate when the sampled matrix inversion (SMI) or Gram-Schmidt (GS) algorithm are employed. It has been previously shown that the steady-state solution for the optimal weights is identical for both constrained and reduced unconstrained problems. It is shown that if the SMI or GS algorithm is employed, then the transient weighting vector solution for the constrained problem is identical to the equivalent transient weight vector solution for the reduced unconstrained implementation
Keywords
antenna phased arrays; antenna theory; convergence of numerical methods; optimisation; signal processing; telecommunications computing; Gram-Schmidt algorithm; antenna phased arrays; convergence; linearly constrained adaptive array; open-loop implementation; optimal weights; optimization algorithm; sampled matrix inversion; signal processing; steady-state solution; transient weighting vector solution; Adaptive arrays; Antenna arrays; Convergence; Covariance matrix; Degradation; Interference cancellation; Interference constraints; Noise cancellation; Steady-state; Vectors;
fLanguage
English
Journal_Title
Aerospace and Electronic Systems, IEEE Transactions on
Publisher
ieee
ISSN
0018-9251
Type
jour
DOI
10.1109/7.53459
Filename
53459
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