Title :
CFAR detection and estimation for STAP radar
Author :
Reed, I.S. ; Gau, Y.L. ; Truong, T.K.
Author_Institution :
Dept. of Electr. Eng. Syst., Univ. of Southern California, Los Angeles, CA, USA
fDate :
7/1/1998 12:00:00 AM
Abstract :
The algorithm presented here provides both a constant false-alarm rate (CFAR) detection and a maximum likelihood (ML) Doppler-bearing estimator of a target in a background of unknown Gaussian noise. A target is detected, and its parameters estimated within each range gate by evaluating a statistical test for each Doppler-angle cell and by selecting the cell with maximum output and finally comparing it with a threshold. Its CFAR performance is analyzed by the use of the sample matrix inversion (SMI) method and is evaluated in the cases of a fully adaptive space-time adaptive processing (STAP) and two partially adaptive STAPs. The performances of these criteria show that the probability of detection is a function only of the sample size K used to estimate the covariance matrix and a generalized signal-to-noise ratio. The choice of the number K is a tradeoff between performance and computational complexity. The performance curves demonstrate that the finer the resolution is, the poorer the detection capability. That means that one can trade off the accuracy of ML estimation with the performance of the CFAR detection criterion
Keywords :
Doppler radar; Gaussian noise; adaptive estimation; adaptive filters; adaptive signal detection; airborne radar; computational complexity; covariance matrices; direction-of-arrival estimation; matrix inversion; maximum likelihood estimation; radar clutter; radar computing; radar detection; radar signal processing; 2D adaptive filtering algorithm; CFAR detection; Doppler-angle cell; airborne radar; coherent pulsed Doppler radar; computational complexity; covariance matrix; fully adaptive space-time adaptive processing; generalized signal-to-noise ratio; maximum likelihood Doppler-bearing estimator; partially adaptive space-time adaptive processing; probability of detection; sample matrix inversion method; sample size dependence; space-time adaptive processing radar; statistical test; target detector; unknown Gaussian noise background; Computational complexity; Covariance matrix; Gaussian noise; Maximum likelihood detection; Maximum likelihood estimation; Parameter estimation; Performance analysis; Radar detection; Signal to noise ratio; Testing;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
