Rapid convergence by cascading Applebaum adaptive arrays

Author

Ganz, Matthew W.

Author_Institution

Lincoln Lab., MIT, Lexington, MA, USA

Volume

30

Issue

2

fYear

1994

fDate

4/1/1994 12:00:00 AM

Firstpage

298

Lastpage

306

Abstract

An adaptive array architecture is described which has improved convergence speed over the conventional Applebaum array when the eigenvalue spread of the input signal covariance matrix is large. The architecture uses N+1 Applebaum adaptive arrays in a two-layer cascaded configuration. The gain constants in the first layer are set so that large interfering sources are quickly nulled, but small interfering sources are suppressed more slowly. Since the first layer removes the large interfering signals, the gain constant for the second layer can be set to a large value to quickly null the smaller interferers. The adaptation time is examined for several combinations of signal levels and array sizes. It is shown that, in many signal environments, the computational requirements for the cascaded array compare favorably with those of conventional sample matrix inversion (SMI) methods for large arrays

Keywords

antenna phased arrays; antenna theory; array signal processing; computational complexity; eigenvalues and eigenfunctions; signal processing; Applebaum array; adaptation time; adaptive array architecture; cascading Applebaum adaptive arrays; computational requirements; convergence speed; eigenvalue spread; gain constants; input signal covariance matrix; interfering sources; sample matrix inversion; two-layer cascaded configuration; Acceleration; Adaptive arrays; Convergence; Covariance matrix; Eigenvalues and eigenfunctions; Equations; Feedback loop; Laboratories; Least squares approximation; Signal generators;

fLanguage

English

Journal_Title

Aerospace and Electronic Systems, IEEE Transactions on

Publisher

ieee

ISSN

0018-9251

Type

jour

DOI

10.1109/7.272255

Filename

272255