Multistatic Collaborative Imaging for Shipborne GNSS-S Radar: Method and Experimental Verification

Global navigation satellite system (GNSS) signals have many advantages, such as numerous satellites and global coverage. There will be huge application potential when utilized as electromagnetic illuminators to construct a passive radar. However, because of GNSS signal power limitations, the signal-...

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Bibliographic Details
Published in:IEEE geoscience and remote sensing letters 2024, Vol.21, p.1-5
Main Authors: Gao, Wenning, Yue, Fuzhan, Xia, Zhenghuan, Xue, Changhu, Liu, Zongqiang, Zhao, Zhilong, Zhang, Chuang, Zhang, Yao, Cui, Zhiying
Format: Article
Language:English
Subjects:
Algorithms
Aperture imaging
Coherent scattering
Collaboration
Demodulation
Doppler effect
Doppler sonar
Echoes
Electromagnetic interference
Global navigation satellite system
Global navigation satellite system-based synthetic aperture radar technology (GNSS-S) radar
Illuminators
Image enhancement
Image quality
images fusion
Imaging
Interference
maritime target imaging
multistatic synthetic aperture radar (SAR)
Navigation
Navigation satellites
Navigation systems
Navigational satellites
Phase locked loops
Radar
Radar antennas
Radar imaging
Reference signals
Satellite imagery
Satellite tracking
Satellites
Signal to noise ratio
Spaceborne radar
Synthetic apertures
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Summary:Global navigation satellite system (GNSS) signals have many advantages, such as numerous satellites and global coverage. There will be huge application potential when utilized as electromagnetic illuminators to construct a passive radar. However, because of GNSS signal power limitations, the signal-to-noise ratio (SNR) of single satellite imaging is often low and vulnerable to electromagnetic interference. The image quality will be greatly enhanced if the signal energy of several GNSS satellites can be fully exploited. However, it is a huge challenge to achieve the coherence of multisatellite signals because different satellites have distinct imaging geometries and motion Doppler. In order to suppress interference and produce images with a high SNR, this research presents a multistatic coherent synthetic aperture imaging method. To demodulate and decode the scattered echoes, a phase-locked loop (PLL) is first utilized to track direct signals from several satellites to create reference signals with constant phases. Then, secondary demodulation functions are constructed to remove the residual Doppler frequency. Finally, the back-projection algorithm is used to perform collaborative coherent imaging on multistatic GNSS echoes. A shipboard experiment was conducted to verify the method. A high-quality image of the ship was obtained in a synthetic aperture time of 3 s by collaborative imaging of six BDS satellites.
ISSN:1545-598X
1558-0571
DOI:10.1109/LGRS.2024.3398577