Analytical Approximation Model for Quadratic Phase Error Introduced by Orbit Determination Errors in Real-Time Spaceborne SAR Imaging

Xiaoyu Yan,Holger Nies,Jie Chen,Otmar Loffeld

doi:10.3390/rs11141663

Xiaoyu Yan, Holger Nies + Show 2 more

Open Access

https://doi.org/10.3390/rs11141663

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Journal: Remote sensing	Publication Date: Jul 12, 2019
Citations: 5	License type: CC BY 4.0

Affiliation: Beihang University, University of Siegen

Abstract

Research on real-time spaceborne synthetic aperture radar (SAR) imaging has emerged as satellite computation capability has increased and applications of SAR imaging products have expanded. The orbit determination data of a spaceborne SAR platform are essential for the SAR imaging procedure. In real-time SAR imaging, onboard orbit determination data cannot achieve a level of accuracy that is equivalent to the orbit ephemeris in ground-based SAR processing, which requires a long processing time using common ground-based SAR imaging procedures. It is important to study the influence of errors in onboard real-time orbit determination data on SAR image quality. Instead of the widely used numerical simulation method, an analytical approximation model of the quadratic phase error (QPE) introduced by orbit determination errors is proposed. The proposed model can provide approximation results at two granularities: approximations with a satellite’s true anomaly as the independent variable and approximations for all positions in the satellite’s entire orbit. The proposed analytical approximation model reduces simulation complexity, extent of calculations, and the processing time. In addition, the model reveals the core of the process by which errors are transferred to QPE calculations. A detailed comparison between the proposed method and a numerical simulation method proves the correctness and reliability of the analytical approximation model. With the help of this analytical approximation model, the technical parameter iteration procedure during the early-stage development of an onboard real-time SAR imaging mission will likely be accelerated.

Highlights

Real-time synthetic aperture radar (SAR) imaging has always been a research focus in certain applications
To calculate the velocity vector term in Equation (10), we propose using the velocity vector of a satellite traveling in a circular orbit Vs in our analytical approximation model rather than using Vst
The analytical approximation model is evaluated by comparing it with the Monte Carlo simulation approach

Summary

Introduction

Real-time synthetic aperture radar (SAR) imaging has always been a research focus in certain applications. In typical methods used to process SAR echo data, a high-accuracy orbit ephemeris is applied in the ground-based processing system, and state vectors, i.e., position and velocity vectors of the SAR satellite, are determined with high accuracy. This kind of high-accuracy orbit ephemeris is only generated hours, days, or even weeks after a single SAR observation [19]. It is acknowledged that this approach to orbit determination has relatively low accuracy in the state vectors of SAR satellites compared with the high-accuracy orbit ephemeris It remains the best, and possibly the only, onboard orbit determination method that is available for real-time SAR imaging

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