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access icon openaccess Robust space-time adaptive processing based on covariance matrix reconstruction and steering vector correction

  • Author(s): Xueyao Hu 1 ; Xinyu Zhang 2 ; Yang Li 1 ; Hongyu Wang 1 ; Yanhua Wang 1
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  • Source: Volume 2019, Issue 21, November 2019, p. 7932 – 7935
    DOI:  10.1049/joe.2019.0708 , Online ISSN 2051-3305
This is an open access article published by the IET under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/)
Received 25/02/2019, Accepted 02/05/2019, Published 13/08/2019

Clutter presents considerable heterogeneity in forward-looking airborne radar (FLAR) applications and conventional space-time adaptive processing (STAP) methods are sensitive to model mismatch. As a result, when a strong target signal contaminates the training samples, despite the use of guard cells, the performance of conventional STAP methods degrades significantly. In this study, a robust method, which involves reconstructing a target-free covariance matrix and correcting the presumed steering vector to prevent target cancellation in FLAR, is proposed. First, the target-free covariance matrix is reconstructed through integrating the spatial–temporal spectrum over a sector separated from the desired frequency and direction of targets. Subsequently, the mismatch between presumed steering vector and actual steering vector is corrected via quadratic optimisation. In addition, the processing scheme is applied to real-measured clutter data, and the experimental results validate the effectiveness of the proposed method.

Inspec keywords: radar detection; radar signal processing; radar clutter; airborne radar; array signal processing; covariance matrices; space-time adaptive processing

Other keywords: presumed steering vector; steering vector correction; conventional space-time adaptive processing methods; target-free covariance matrix; actual steering vector; strong target signal; conventional STAP methods degrades; robust method; FLAR; robust space-time adaptive processing; covariance matrix reconstruction; target cancellation; airborne radar applications; processing scheme; considerable heterogeneity

Subjects: Signal processing and detection; Other topics in statistics; Radar equipment, systems and applications; Algebra; Radar theory

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