Direction finding via joint diagonalization

Author

Weiss, A.J. ; Friedlander, B.

Author_Institution

Dept. of Electr. Eng. Syst., Tel Aviv Univ., Israel

fYear

1996

fDate

24-26 Jun 1996

Firstpage

66

Lastpage

69

Abstract

An approach to array processing (i.e., direction finding, signal separation and reconstruction, and calibration) based on the analytical constant modulus algorithm is considered. The main advantage of this approach is that the multidimensional search associated with maximum likelihood based estimators or the single dimensional search associated with MUSIC type methods are eliminated. The sensor array elements are assumed to have the same, up to a multiplicative constant, angle dependent, unknown gain pattern. We show that under this assumption it is possible to estimate the array response matrix and then use the result for direction finding, if the nominal array manifold is known, at least approximately. It is also possible to use the estimated array response matrix in order to separate and reconstruct the signals, or calibrate the array shape or response

Keywords

array signal processing; calibration; direction-of-arrival estimation; matrix algebra; signal reconstruction; DOA; angle dependent gain pattern; array manifold; array processing; array response matrix estimation; array shape; calibration; constant modulus algorithm; direction finding; joint diagonalization; linear array; sensor array elements; signal reconstruction; signal separation; Algorithm design and analysis; Array signal processing; Calibration; Maximum likelihood estimation; Multidimensional systems; Multiple signal classification; Sensor arrays; Shape; Signal analysis; Source separation;

fLanguage

English

Publisher

ieee

Conference_Titel

Statistical Signal and Array Processing, 1996. Proceedings., 8th IEEE Signal Processing Workshop on (Cat. No.96TB10004

Conference_Location

Corfu

Print_ISBN

0-8186-7576-4

Type

conf

DOI

10.1109/SSAP.1996.534821

Filename

534821