Title :
Estimation of directions of arrival of multiple scattered sources
Author :
Ghogho, Mounir ; Besson, Olivier ; Swami, Ananthram
Author_Institution :
Dept. of Electron. & Electr. Eng., Strathclyde Univ., Glasgow, UK
fDate :
11/1/2001 12:00:00 AM
Abstract :
We consider the problem of estimating the directions of arrival (DOA) of multiple sources in the presence of local scattering. This problem is encountered in wireless communications due to the presence of scatterers in the vicinity of the mobile or when the signals propagate through a random inhomogeneous medium. Assuming a uniform linear array (ULA), we develop DOA estimation algorithms based on covariance matching applied to a reduced-size statistic obtained from the sample covariance matrix after redundancy averaging. Next, a computationally efficient estimator based on AR modelling of the coherence loss function is derived. A theoretical expression for the asymptotic covariance matrix of this estimator is derived. Finally, the corresponding Cramer-Rao bounds (CRBs) are derived. Despite its simplicity, the AR-based estimator is shown to possess performance that is nearly as good as that of the covariance matching method
Keywords :
array signal processing; autoregressive processes; covariance matrices; direction-of-arrival estimation; electromagnetic wave scattering; inhomogeneous media; land mobile radio; linear antenna arrays; radiowave propagation; random media; AR modelling; AR-based estimator; Cramer-Rao bounds; DOA estimation; DOA estimation algorithms; antenna arrays; asymptotic covariance matrix; coherence loss function; computationally efficient estimator; covariance matching method; direction of arrival estimation; local scattering; mobile radio; multiple scattered sources; radiowave propagation; random inhomogeneous medium; reduced-size statistic; redundancy averaging; sample covariance matrix; uniform linear array; wireless communications; Base stations; Covariance matrix; Degradation; Direction of arrival estimation; Maximum likelihood estimation; Radar scattering; Robustness; Sonar; Spatial coherence; Wireless communication;
Journal_Title :
Signal Processing, IEEE Transactions on
