Abstract

In real application scenario of bistatic forward-looking synthetic aperture radar (BFSAR), ground moving target (GMT) is generally smeared severely in SAR image, due to its unknown range cell migration (RCM) and Doppler frequency migration (DFM). When GMT moves along an unknown curve trajectory, its high-order RCM and DFM (including the second- and third-order terms) would further aggravate the difficulty of GMT refocusing. To address this issue, an efficient GMT refocusing method via keystone-based delay-correlation transform and fast searching Fourier transform (KDCT-FSFT) is proposed. First, the KDCT is proposed to correct the first- to third-order RCMs regardless of target's motion state and position information. Meanwhile, the order of GMT's phase response is reduced as well. Then, FSFT is applied to estimate the third-order Doppler parameter of GMT. In the following, a 2-D fast Fourier transform (2D-FFT) can be applied to integrate the target signal coherently in Doppler parameters domain, where the Doppler centroid and Doppler frequency rate of GMT can be estimated. Finally, with the aforesaid estimated Doppler parameters, RCM and DFM can be well corrected and target with unknown curve motion can be finely refocused. Compared with the existing methods, not only the refocusing accuracy of the proposed method is higher, but also its processing is more efficient, since the procedures in the proposed method are performed with respect to all the range cells in the corresponding aperture, i.e., GMT refocusing is achieved by the 2-D data received in one aperture, rather than along every single range cell. Both the simulation and experimental results are given to validate the effectiveness of the proposed method.

Highlights

  • I N RECENT years, bistatic forward-looking synthetic aperture radar (BFSAR) is increasingly attractive in both civilianManuscript received May 26, 2020; revised July 21, 2020; accepted August 4, 2020

  • When a ground moving target (GMT) is presented in the observation scenario, GMT signal is usually smeared into multiple cells, since its non-cooperative motion inevitably induces unknown range cell migration (RCM) and Doppler frequency migration (DFM)

  • To solve the aforesaid problems, we develop a keystone-based delay correlation transform (KDCT) and fast searching Fourier transform (FSFT)-based refocusing method in BFSAR for GMT with unknown curve motion

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Summary

Introduction

I N RECENT years, bistatic forward-looking synthetic aperture radar (BFSAR) is increasingly attractive in both civilianManuscript received May 26, 2020; revised July 21, 2020; accepted August 4, 2020. Due to the physical separation of transmitter and receiver, BFSAR with a proper geometry can break through the limitations of monostatic SAR and exhibits advantages of high anti-interference and flexibilities. With these superiority and its unique forward-looking observation ability, BFSAR plays a crucial role in modern remote sensing applications, such as autonomous navigation, self-landing and etc [4]–[6]. To effectively refocus GMT, the RCM and DFM, including the high-order terms, caused by GMT’s curve motion should be compensated first. Estimating GMT’s Doppler parameters is one effective way to solve the refocusing problem for GMT with unknown curve motion. The coupling relationship between RCM correction (RCMC) and parameter estimation will further aggravate the difficulty to refocus a GMT with unknown curve motion

Methods
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Conclusion

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