Title :
Eigenanalysis-based space-time adaptive radar: performance analysis
Author :
Haimovich, A.M. ; Berin, M.
Author_Institution :
Dept. of Electr. & Comput. Eng., New Jersey Inst. of Technol., Newark, NJ, USA
Abstract :
The space-time radar problem is well suited to the application of techniques that take advantage of the low rank property of the space-time covariance matrix. The performance of an eigenanalysis-based detector with respect to convergence rate and robustness to calibration errors is analyzed. Analytical expressions are developed for receiver operating curves when the clutter signal environment is assumed to be Gaussian. The curves are derived from the asymptotic expansion of the distribution of the principal components of the covariance matrix. Simulation results are provided to corroborate the theoretical analysis. Examples from the Mountain-Top dataset are used to illustrate the higher convergence rate and increased robustness of the eigenanalysis method.
Keywords :
Gaussian processes; adaptive radar; adaptive signal detection; airborne radar; convergence of numerical methods; covariance matrices; data analysis; digital simulation; eigenvalues and eigenfunctions; numerical analysis; performance evaluation; radar clutter; radar detection; radar tracking; search radar; surveillance; target tracking; telecommunication computing; Mountain-Top dataset; asymptotic expansion; calibration errors; clutter signal; convergence rate; covariance matrix; eigenanalysis; performance analysis; receiver operating curves; robustness; simulation; space-time adaptive radar; space-time covariance matrix; space-time radar; theoretical analysis; Calibration; Convergence; Covariance matrix; Detectors; Error analysis; Performance analysis; Radar applications; Radar detection; Robustness; Spaceborne radar;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
