Abstract
Across-track acceleration is a major source of estimation error of along-track velocity in synthetic-aperture radar (SAR) ground moving-target indication (GMTI). This paper presents the theory and a method of compensating across-track acceleration to improve the accuracy of along-track velocity estimated from single-channel SAR single-look complex data. A unique feature of the proposed method is the utilisation of phase derivatives in the Doppler frequency domain, which is effective for azimuth-compressed signals. The performance of the method was evaluated through experimental data acquired by TerraSAR-X and speed-controlled and measured vehicles. The application results demonstrate a notable improvement in along-track velocity estimates. The amount of along-track velocity correction is particularly significant when a target has irregular motion with a low signal-to-clutter ratio. A discontinuous velocity jump rather than a constant acceleration was also observed and verified through comparison between actual data and simulations. By applying this method, the capability of single-channel SAR GMTI could be substantially improved in terms of accuracy of velocity, and moving direction. However, the method is effective only if the correlation between the actual Doppler phase derivatives and a model derived from the residual Doppler rate is sufficiently high. The proposed method will be applied to X-band SAR systems of KOMPSAT-5 and -6.
Highlights
A unique and popular application of synthetic-aperture radar (SAR) is the monitoring of moving targets [1,2,3,4,5,6], which is a SAR application field of ground moving-target indication (GMTI) [7,8,9,10,11,12]
This paper focuses on compensating across-track acceleration to improve the accuracy of the along-track velocity of ground moving targets from single-look complex (SLC) data obtained by single-channel SAR systems
From the residual Doppler rate estimated in time, a linear phase model in the Doppler frequency domain is given by Equation (15), and it is subtracted from the Doppler phase derivatives, as in Equation (16)
Summary
A unique and popular application of synthetic-aperture radar (SAR) is the monitoring of moving targets [1,2,3,4,5,6], which is a SAR application field of ground moving-target indication (GMTI) [7,8,9,10,11,12]. A number of papers propose various methods for SAR GMTI [8,20,21,22,23], and multi or at least dual-channel SAR systems are efficient and effective for the detection and velocity estimations of ground moving targets [8,10,11,12,17,24,25,26,27,28,29,30]. Data of space-borne single-channel SAR systems are currently far more abundant and are easier to access by general users than space-borne multi or dual-channel SAR data. This paper focuses on compensating across-track acceleration to improve the accuracy of the along-track velocity of ground moving targets from SLC data obtained by single-channel SAR systems
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