Array Interpolation Using Covariance Matrix Completion of Minimum-Size Virtual Array

Sparse arrays increase aperture and resolution capability for direction-of-arrival estimation. Spatial smoothing step in coarray MUSIC algorithm prevents us from using the full coarray; so, there is a limitation for aperture N α and degrees of freedom that are determined by minimum redundancy arrays...

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Bibliographic Details
Published in:IEEE signal processing letters 2017-07, Vol.24 (7), p.1063-1067
Main Authors: Hosseini, Seyed MohammadReza, Sebt, Mohammad Ali
Format: Article
Language:English
Subjects:
Apertures
Array signal processing
Covariance matrices
Direction-of-arrival (DOA)
Interpolation
matrix completion
Minimization
Sensor arrays
sparse arrays
virtual array
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Summary:Sparse arrays increase aperture and resolution capability for direction-of-arrival estimation. Spatial smoothing step in coarray MUSIC algorithm prevents us from using the full coarray; so, there is a limitation for aperture N α and degrees of freedom that are determined by minimum redundancy arrays. Interpolation methods can reduce this limitation and make it possible to use the full coarray of partially augmentable arrays. In interpolation methods based on matrix completion techniques, we should complete an N α × N α Toeplitz matrix. For this purpose, a semidefinite programming (SDP) with O(N α 6 ) complexity should be solved. In this letter, we introduce a set that contains arrays that have the equal aperture with original array and have filled coarray. By selecting the array that have minimum number of sensors in this set, we formulate a new structured matrix completion problem. Numerical examples indicate that the proposed structured matrix completion not only decreases the complexity of SDP problem but also, in many instances, increases the estimation accuracy and probability of resolution.
ISSN:1070-9908
1558-2361
DOI:10.1109/LSP.2017.2708750