Abstract
When high-resolution wide-swath (HRWS) multichannel synthetic aperture radar (MC-SAR) system is used for ocean observation, vast amount of redundant data is generated, significantly limiting its applications. Though compressive sensing (CS)-based method has been applied to the traditional single-channel or dual-channel SAR imaging system, it is no longer applicable for MC-SAR due to the existence of channel error when using the space-time equivalent sampling technique for azimuth signal reconstruction. By analyzing such periodic channel error, i.e., frequency-dependence phase mismatch (FD-PM), in this article, a novel dictionary is constructed for CS-based HRWS MC-SAR imaging after an improved range cell migration correction method is applied. As a result, a novel CS imaging mode is proposed for the ocean moving target based on the sparsity of the target scattering centers, by which the amount of data in MC-SAR can be reduced by sampling below the Nyquist sampling rate and the swath width can be further increased. Experimental results show that the proposed method clearly eliminates the azimuth defocus and blur caused by low sampling rate and FD-PM, and significantly reduces the amount of data to about one-third when compared to sampling at the Nyquist rate.
Highlights
A S AN active observation system, synthetic aperture radar (SAR) has been widely used in marine observation, crop growth observation, environmental detection, and other fieldsManuscript received May 3, 2020; revised November 5, 2020; accepted November 29, 2020
In order to reduce the data volume in the imaging system, in the proposed MC high-resolution wide-swath (HRWS) SAR system, we reduce the sampling rate below Nyquist rate, which means the azimuth-equivalent pulse repetition frequency (PRF) will be lower than the Doppler bandwidth of the moving target
In order to explicitly prove the effectiveness of the RCM correction (RCMC) algorithm, experiments of a single scattering point are designed
Summary
A S AN active observation system, synthetic aperture radar (SAR) has been widely used in marine observation, crop growth observation, environmental detection, and other fields. In order to solve such problem, multiple receive apertures in azimuth have been proposed [5]–[7] Such multichannel SAR (MC-SAR) enables high-resolution wide-swath (HRWS) imaging, in which range ambiguity can be suppressed by transmitting chirp signals and all channels receive echoes simultaneously [8]. A CS-based ground moving target indication method was proposed by sparsely sampling dual-channel SAR data in the azimuth direction [14] In these existing CS-based SAR imaging techniques, the number of pulses and observation channels is generally limited.
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