Space-Time Adaptive Processing Using Random Matrix Theory Under Limited Training Samples

TL;DR

This paper introduces RMT-based STAP algorithms that improve ground clutter suppression in airborne radar with limited training samples by optimally estimating the clutter-plus-noise covariance matrix.

Contribution

It develops novel RMT-based STAP algorithms for both full and reduced-dimension systems, enhancing performance with fewer training samples compared to traditional methods.

Findings

RMT-FD-STAP and RMT-RD-STAP outperform existing algorithms with limited training data.

The proposed methods effectively estimate the covariance matrix eigenvalues for better clutter suppression.

Theoretical analysis and simulations confirm the performance advantages of the new algorithms.

Abstract

Space-time adaptive processing (STAP) is one of the most effective approaches to suppressing ground clutters in airborne radar systems. It basically takes two forms, i.e., full-dimension STAP (FD-STAP) and reduced-dimension STAP (RD-STAP). When the numbers of clutter training samples are less than two times their respective system degrees-of-freedom (DOF), the performances of both FD-STAP and RD-STAP degrade severely due to inaccurate clutter estimation. To enhance STAP performance under the limited training samples, this paper develops a STAP theory with random matrix theory (RMT). By minimizing the output clutter-plus-noise power, the estimate of the inversion of clutter plus noise covariance matrix (CNCM) can be obtained through optimally manipulating its eigenvalues, and thus producing the optimal STAP weight vector. Two STAP algorithms, FD-STAP using RMT (RMT-FD-STAP) and RD-STAP using RMT (RMT-RD-STAP), are proposed. It is found that both RMT-FD-STAP and RMT-RD-STAP greatly outperform other-related STAP algorithms when the numbers of training samples are larger than their respective clutter DOFs, which are much less than the corresponding system DOFs. Theoretical analyses and simulation demonstrate the effectiveness and the performance advantages of the proposed STAP algorithms.