Paper Info
Title
Maximum-likelihood bearing estimation with partly calibrated arrays in spatially correlated noise fields
Abstract
The problem of using a partly calibrated array for maximum likelihood (ML) bearing estimation of possibly coherent signals buried in unknown correlated noise fields is shown to admit a neat solution under fairly general conditions. More exactly, this paper assumes that the array contains some calibrated sensors, whose number is only required to be larger than the number of signals impinging on the array, and also that the noise in the calibrated sensors is uncorrelated with the noise in the other sensors. These two noise vectors, however, may have arbitrary spatial autocovariance matrices. Under these assumptions the many nuisance parameters (viz., the elements of the signal and noise covariance matrices and the transfer and location characteristics of the uncalibrated sensors) can be eliminated from the likelihood function, leaving a significantly simplified concentrated likelihood whose maximum yields the ML bearing estimates. The ML estimator introduced in this paper, and referred to as MLE, is shown to be asymptotically equivalent to a recently proposed subspace-based bearing estimator called UNCLE and rederived herein by a much simpler approach than in the original work. A statistical analysis derives the asymptotic distribution of the MLE and UNCLE estimates, and proves that they are asymptotically equivalent and statistically efficient. In a simulation study, the MLE and UNCLE methods are found to possess very similar finite-sample properties as well. As UNCLE is computationally more efficient, it may be the preferred technique in a given application
Year
DOI
Venue
1996
10.1109/78.492542
IEEE Transactions on Signal Processing
Keywords
Field
DocType
calibration,computational complexity,covariance matrices,direction-of-arrival estimation,interference (signal),maximum likelihood estimation,noise,MLE,UNCLE,asymptotic distribution,calibrated sensors,computational efficiency,finite-sample properties,maximum-likelihood bearing estimation,noise vectors,partly calibrated arrays,possibly coherent signals,simulation,spatial autocovariance matrices,spatially correlated noise fields,statistical analysis,subspace-based bearing estimator
Autocovariance,Likelihood function,Control theory,Phase noise,Antenna array,Algorithm,Covariance matrix,Statistics,Mathematics,Covariance,Estimator,Asymptotic distribution
Journal
Volume
Issue
ISSN
44
4
1053-587X
Citations 
PageRank 
References 
12
14.09
15
Authors
4
Name
Order
Citations
PageRank
Petre Stoica17959915.30
M. Viberg2917188.13
K.M. Wong31459147.00
Q. Wu48527.90