Model-based clutter cancellation based on enhanced knowledge-aided parametric covariance estimation

Aerospace radar operation requires robust target detection in the presence of strong ground clutter returns. Space-time adaptive processing (STAP) is a leading approach to cull weak target signals from a strong clutter background. A scene comprised of heterogeneous clutter degrades typical STAP implementation by corrupting training data, thereby leading to covariance estimation error, corresponding adaptive clutter filter mismatch, and loss of detection performance. In the knowledge-aided parametric covariance estimation (KAPE) method, the processor estimates the parameters of a validated clutter covariance model to tailor the clutter filter response to rapid changes in heterogeneous clutter environments. Computational burden and array manifold estimation, given antenna complex gain errors, are two primary concerns when implementing KAPE. This paper develops and characterizes an enhanced KAPE (E-KAPE) approach. Specifically, we develop a computationally efficient implementation via application of Gram-Schmidt orthonormalization to the modeled clutter manifold and discuss an iterative approach to estimate complex gain errors from channel-to-channel, leading to substantial improvement in model-based clutter cancellation potential. For the specific simulation results shown, we find a 9-dB improvement in signal-to-interference-plus-noise ratio loss for our proposed approach relative to the original KAPE method. Furthermore, for these cases, we show that our E-KAPE method outperforms conventional STAP algorithms in the presence of homogeneous and heterogeneous clutter.

[1]  R. Klemm Principles of Space-Time Adaptive Processing , 2002 .

[2]  William L. Melvin,et al.  Adaptive detection in dense target environments , 2001, Proceedings of the 2001 IEEE Radar Conference (Cat. No.01CH37200).

[3]  M. Wicks,et al.  Practical joint domain localised adaptive processing in homogeneous and nonhomogeneous environments. Part 2: Nonhomogeneous environments , 2000 .

[4]  William L. Melvin,et al.  Assessment of multichannel airborne radar measurements for analysis and design of space-time processing architectures and algorithms , 1996, Proceedings of the 1996 IEEE National Radar Conference.

[5]  Karl Gerlach,et al.  Airborne/spacebased radar STAP using a structured covariance matrix , 2003 .

[6]  L.E. Brennan,et al.  Theory of Adaptive Radar , 1973, IEEE Transactions on Aerospace and Electronic Systems.

[7]  Pierfrancesco Lombardo,et al.  Nonlinear STAP processing , 1999 .

[8]  W.L. Melvin,et al.  Knowledge-aided signal processing: a new paradigm for radar and other advanced sensors , 2006, IEEE Transactions on Aerospace and Electronic Systems.

[9]  N.A. Goodman,et al.  STAP training through knowledge-aided predictive modeling [radar signal processing] , 2004, Proceedings of the 2004 IEEE Radar Conference (IEEE Cat. No.04CH37509).

[10]  A. Haimovich,et al.  The eigencanceler: adaptive radar by eigenanalysis methods , 1996, IEEE Transactions on Aerospace and Electronic Systems.

[11]  J.R. Guerci,et al.  STAP with knowledge-aided data pre-whitening , 2004, Proceedings of the 2004 IEEE Radar Conference (IEEE Cat. No.04CH37509).

[12]  W.L. Melvin,et al.  A STAP overview , 2004, IEEE Aerospace and Electronic Systems Magazine.

[13]  J.R. Guerci,et al.  Knowledge-aided adaptive radar at DARPA: an overview , 2006, IEEE Signal Processing Magazine.

[14]  W.L. Melvin,et al.  A knowledge-aided GMTI detection architecture [radar signal processing] , 2004, Proceedings of the 2004 IEEE Radar Conference (IEEE Cat. No.04CH37509).

[15]  Joseph R. Guerci,et al.  On Periodic Autoregressive Processes Estimation , 2000 .

[16]  R. Kumaresan,et al.  Data-Adaptive Detection of a Weak Signal , 1983, IEEE Transactions on Aerospace and Electronic Systems.

[17]  Eric Hung,et al.  A Fast Beamforming Algorithm for Large Arrays , 1983, IEEE Transactions on Aerospace and Electronic Systems.

[18]  William L. Melvin,et al.  Space-time adaptive radar performance in heterogeneous clutter , 2000, IEEE Trans. Aerosp. Electron. Syst..

[19]  R.C. DiPietro,et al.  Extended factored space-time processing for airborne radar systems , 1992, [1992] Conference Record of the Twenty-Sixth Asilomar Conference on Signals, Systems & Computers.

[20]  Rodrigo C. de Lamare,et al.  Reduced-Rank STAP Schemes for Airborne Radar Based on Switched Joint Interpolation, Decimation and Filtering Algorithm , 2010, IEEE Transactions on Signal Processing.

[21]  Michael Frankfurter,et al.  Numerical Recipes In C The Art Of Scientific Computing , 2016 .

[22]  A. Farina,et al.  Nonlinear nonadaptive space-time processing for airborne early warning radar , 1998 .

[23]  Bernard Mulgrew,et al.  Sparse LCMV beamformer design for suppression of ground clutter in airborne radar , 1995, IEEE Trans. Signal Process..

[24]  Joseph R. Guerci,et al.  Space-Time Adaptive Processing for Radar , 2003 .

[25]  W.L. Melvin,et al.  An approach to knowledge-aided covariance estimation , 2006, IEEE Transactions on Aerospace and Electronic Systems.

[26]  Don H. Johnson,et al.  Array Signal Processing: Concepts and Techniques , 1993 .

[27]  J. Billingsley,et al.  Low-Angle Radar Land Clutter: Measurements and Empirical Models , 2002 .

[28]  I. Reed,et al.  Rapid Convergence Rate in Adaptive Arrays , 1974, IEEE Transactions on Aerospace and Electronic Systems.

[29]  William H. Press,et al.  The Art of Scientific Computing Second Edition , 1998 .

[30]  Joseph R. Guerci,et al.  Space-time Beamforming with Knowledge-Aided Constraints , 2003 .

[31]  Daniel R. Fuhrmann,et al.  A CFAR adaptive matched filter detector , 1992 .

[32]  William L. Melvin,et al.  A Knowledge-Aided GMTI Detection Architecture , 2004 .

[33]  James Ward,et al.  Space-time adaptive processing for airborne radar , 1998 .

[34]  J. D. Hiemstra Colored diagonal loading , 2002, Proceedings of the 2002 IEEE Radar Conference (IEEE Cat. No.02CH37322).