Abstract
Sidelobe reduction is a very primary task for synthetic aperture radar (SAR) images. Various methods have been proposed for broadside SAR, which can suppress the sidelobes effectively while maintaining high image resolution at the same time. Alternatively, squint SAR, especially highly squint SAR, has emerged as an important tool that provides more mobility and flexibility and has become a focus of recent research studies. One of the research challenges for squint SAR is how to resolve the severe range-azimuth coupling of echo signals. Unlike broadside SAR images, the range and azimuth sidelobes of the squint SAR images no longer locate on the principal axes with high probability. Thus the spatially variant apodization (SVA) filters could hardly get all the sidelobe information, and hence the sidelobe reduction process is not optimal. In this paper, we present an improved algorithm called double spatially variant apodization (D-SVA) for better sidelobe suppression. Satisfactory sidelobe reduction results are achieved with the proposed algorithm by comparing the squint SAR images to the broadside SAR images. Simulation results also demonstrate the reliability and efficiency of the proposed method.
Highlights
Synthetic aperture radar (SAR) transmits linear frequency modulation (LFM) signals and receives the backscattered echoes from Earth observation scenes
We propose a novel sidelobe reduction algorithm using double spatially variant apodization (D-SVA) for squint SAR images
According to the time shifting property, the squint SAR image can be corrected as the broadside
Summary
Synthetic aperture radar (SAR) transmits linear frequency modulation (LFM) signals and receives the backscattered echoes from Earth observation scenes. For squint SAR images, such algorithms could obtain poor sidelobe reduction results To address this issue, Castillo-Rubio et al proposed an SVA algorithm for squint SAR images [9], in which the authors implemented the range migration algorithm (RMA) for image formation. By taking advantages of sampling parameters recalculation and nearest interpolation computation, the authors were able to extract most of the sidelobe information for the squint SAR images. This algorithm is complex and time consuming as it used 5-tabs SVA methods. We propose a novel sidelobe reduction algorithm using double spatially variant apodization (D-SVA) for squint SAR images. Simulation results demonstrate that this algorithm is reliable and efficient
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