Modified Blind Equalization Algorithm Based on Cyclostationarity for Contaminated Reference Signal in Airborne PBR

In airborne passive bistatic radar (PBR), the reference channel toward the opportunity illuminator is applied to receive the direct-path signal as the reference signal. In the actual scenario, the reference signal is contaminated by the multipath signals easily. Unlike the multipath signal in traditional ground PBR system, the multipath signal in the airborne PBR owns not only the time delay but also the Doppler frequency. The contaminated reference signal can cause the spatial-temporal clutter spectrum to expand and the false targets to appear. The performance of target detection is impacted severely. However, the existing blind equalization algorithm is unavailable for the contaminated reference signal in airborne PBR. In this paper, the modified blind equalization algorithm is proposed to suppress the needless multipath signal and restore the pure reference signal. Aiming at the Doppler frequency of multipath signal, the high-order moment information and the cyclostationarity of source signal are exploited to construct the new cost function for the phase constraint, and the complex value back propagation (BP) neural network is exploited to solve the constraint optimization problem for the better convergence. In final, the simulation experiments are conducted to prove the feasibility and superiority of proposed algorithm.

[1]  Xiang Li,et al.  SPACE-TIME ADAPTIVE PROCESSING BASED ON WEIGHTED REGULARIZED SPARSE RECOVERY , 2012 .

[2]  J. Guerci,et al.  Improved clutter mitigation performance using knowledge-aided space-time adaptive processing , 2006, IEEE Transactions on Aerospace and Electronic Systems.

[3]  M.C. Wicks,et al.  Space-time adaptive processing: a knowledge-based perspective for airborne radar , 2006, IEEE Signal Processing Magazine.

[4]  Jun Lu,et al.  A Multi-Channel Partial-Update Algorithm for Sea Clutter Suppression in Passive Bistatic Radar , 2018, 2018 IEEE 10th Sensor Array and Multichannel Signal Processing Workshop (SAM).

[5]  Yongming Huang,et al.  Sea Clutter Cancellation for Passive Radar Sensor Exploiting Multi-Channel Adaptive Filters , 2019, IEEE Sensors Journal.

[6]  F. Colone,et al.  Multifrequency integration in FM radio-based passive bistatic radar. Part II: Direction of arrival estimation , 2013, IEEE Aerospace and Electronic Systems Magazine.

[7]  Jonathon A. Chambers,et al.  Fractional order constant modulus blind algorithms with application to channel equalisation , 2014 .

[8]  Pierfrancesco Lombardo,et al.  Space-time constant modulus algorithm for multipath removal on the reference signal exploited by passive bistatic radar , 2009 .

[9]  Hongbin Li,et al.  A Bayesian Parametric Test for Multichannel Adaptive Signal Detection in Nonhomogeneous Environments , 2010, IEEE Signal Processing Letters.

[10]  Karl Woodbridge,et al.  Air target detection using airborne passive bistatic radar , 2010 .

[11]  Raja Syamsul Azmir Raja Abdullah,et al.  Analysis on Target Detection and Classification in LTE Based Passive Forward Scattering Radar , 2016, Sensors.

[12]  Fabiola Colone,et al.  Multi-Frequency Target Detection Techniques for DVB-T Based Passive Radar Sensors , 2016, Sensors.

[13]  Michael Edrich,et al.  Design and performance evaluation of a mature FM/DAB/DVB-T multi-illuminator passive radar system , 2014 .

[14]  A. Constantinides,et al.  New normalized constant modulus algorithms with relaxation , 1997, IEEE Signal Processing Letters.

[15]  Krzysztof S. Kulpa,et al.  DPCA Detection of Moving Targets in Airborne Passive Radar , 2012, IEEE Transactions on Aerospace and Electronic Systems.

[16]  Dezhong Peng,et al.  Second-Order Cyclostationary Statistics-Based Blind Source Extraction From Convolutional Mixtures , 2017, IEEE Access.

[17]  Karim Abed-Meraim,et al.  Blind source-separation using second-order cyclostationary statistics , 2001, IEEE Trans. Signal Process..

[18]  F. Colone,et al.  Multifrequency integration in FM radio-based passive bistatic radar. Part I: Target detection , 2013, IEEE Aerospace and Electronic Systems Magazine.

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

[20]  Jun Wang,et al.  Cascaded Suppression Method for Airborne Passive Radar With Contaminated Reference Signal , 2019, IEEE Access.

[21]  P. Howland Editorial: Passive radar systems , 2005 .

[22]  B. Dawidowicz,et al.  Detection of moving targets with multichannel airborne passive radar , 2012, IEEE Aerospace and Electronic Systems Magazine.

[23]  Hongbo Sun,et al.  Space–time interference analysis and suppression for airborne passive radar using transmissions of opportunity , 2014 .

[24]  Qinglong Bao,et al.  An Experimental Study of Passive Bistatic Radar Using Uncooperative Radar as a Transmitter , 2015, IEEE Geoscience and Remote Sensing Letters.

[25]  Yuan Feng,et al.  Interference suppression using joint spatio-temporal domain filtering in passive radar , 2015, 2015 IEEE Radar Conference (RadarCon).

[26]  Huadong Meng,et al.  Registration-based compensation using sparse representation in conformal-array STAP , 2010, Signal Process..

[27]  B. Dawidowicz,et al.  Suppression of the ground clutter in airborne PCL radar using DPCA technique , 2009, 2009 European Radar Conference (EuRAD).