A polynomial rooting approach to super-resolution array design

Author

Dowlut, Naushad ; Manikas, Athanassios

Author_Institution

Toronto Design Centre, Motorola Canada, Ont., Canada

Volume

48

Issue

6

fYear

2000

fDate

6/1/2000 12:00:00 AM

Firstpage

1559

Lastpage

1569

Abstract

This paper is concerned with the design of super-resolution direction finding (DF) arrays that satisfy prespecified performance levels, such as detection-resolution thresholds and Cramer-Rao bounds on error variance. The sensor placement problem is formulated in the framework of subspace-based DF techniques and a novel polynomial rooting approach to the design problem, based on the new concept of the “sensor locator polynomial (SLP),” is proposed. This polynomial is constructed using the prespecified performance levels, and its roots yield the sensor locations of the desired array. The distinguishing feature of the proposed technique is that it hinges on the properties of the array manifold, which plays a central role in all subspace-based DF algorithms

Keywords

array signal processing; direction-of-arrival estimation; matrix algebra; polynomials; signal resolution; Cramer-Rao bounds; DOA estimation; array manifold; detection-resolution thresholds; error variance; linear array; matrix; performance levels; planar array; polynomial rooting approach; sensor locator polynomial; sensor placement problem; subspace-based DF algorithms; super-resolution array design; super-resolution direction finding arrays; Algorithm design and analysis; Apertures; Associate members; Covariance matrix; Maximum likelihood estimation; Polynomials; Sensor arrays; Sensor phenomena and characterization; Signal processing algorithms; Signal resolution;

fLanguage

English

Journal_Title

Signal Processing, IEEE Transactions on

Publisher

ieee

ISSN

1053-587X

Type

jour

DOI

10.1109/78.845915

Filename

845915