Title :
Structured covariance estimation for space-time adaptive processing
Author :
Barton, Timothy A. ; Smith, Steven T.
Author_Institution :
Lincoln Lab., MIT, Lexington, MA, USA
Abstract :
Adaptive algorithms require a good estimate of the interference covariance matrix. In situations with limited sample support such an estimate is not available unless there is structure to be exploited. In applications such as radar space-time adaptive processing (STAP) the underlying covariance matrix is structured (e.g., block Toeplitz), and it is possible to exploit this structure to arrive at improved covariance estimates. Several structured covariance estimators have been proposed for this purpose. The efficacy of several of these are analyzed in this paper in the context of a variety of STAP algorithms. The SINR losses resulting from the different methods are compared. An example illustrating the superior performance resulting from a new maximum likelihood algorithm (based upon the expectation-maximization algorithm) is demonstrated using simulation and experimental data
Keywords :
Toeplitz matrices; adaptive radar; adaptive signal processing; array signal processing; covariance matrices; interference suppression; maximum likelihood estimation; radar clutter; radar signal processing; SINR losses; STAP algorithms; STAP processing; block Toeplitz matrix; expectation-maximization algorithm; interference covariance matrix; maximum likelihood algorithm; radar clutter; radar processing; space-time adaptive processing; structured covariance estimation; Adaptive algorithm; Algorithm design and analysis; Clutter; Covariance matrix; Interference; Iterative algorithms; Laboratories; Maximum likelihood estimation; Space technology; Yield estimation;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 1997. ICASSP-97., 1997 IEEE International Conference on
Conference_Location :
Munich
Print_ISBN :
0-8186-7919-0
DOI :
10.1109/ICASSP.1997.604617
