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Journals & Magazines >IEEE Geoscience and Remote Se... >Volume: 13 Issue: 8

Experimental Results of Passive SAR Imaging Using DVB-T Illuminators of Opportunity

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Damian Gromek; Krzysztof Kulpa; Piotr Samczyński
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Abstract:

In this letter, pioneering experimental results of passive synthetic aperture radar (SAR) imaging are presented. The classical active SAR radar operates in monostatic geo...Show More

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Abstract:

In this letter, pioneering experimental results of passive synthetic aperture radar (SAR) imaging are presented. The classical active SAR radar operates in monostatic geometry. The SAR sensor presented in this letter is a passive radar utilizing commercial Digital Video Broadcasting-Terrestrial transmitters as illuminators of opportunity. It works in a bistatic configuration, where the receiver is placed on a moving platform and the transmitter is placed on the ground and is stationary. The imaged scenes are stationary surfaces on Earth such as agriculture or urban areas, buildings, etc. In this letter, pioneering results of signal processing verified by a measurement campaign are presented. In the experiment, two synchronized passive radar receivers were mounted on a small airborne platform. The main goal of the presented experiment was to verify the possibility of ground imaging using passive SAR technology and validate previously presented theoretical results.
Published in: IEEE Geoscience and Remote Sensing Letters ( Volume: 13, Issue: 8, August 2016)
Page(s): 1124 - 1128
Date of Publication: 15 June 2016

ISSN Information:

DOI: 10.1109/LGRS.2016.2571901
References is not available for this document.
Contents

I. Introduction

One of the most popular methods for Earth surface imaging is the synthetic aperture radar (SAR) technique. It was proposed for the first time in 1951 by Carl Willey from the Goodyear Aircraft Corporation [1], [2]. Since that time, SAR has been intensively developed, and many new concepts of image creation have been proposed [3], [4]. Nowadays, SAR imaging has entered a stage of technological maturity and is widely used in sensors mounted on different kinds of moving platforms such as satellites, aircraft, and unmanned aerial vehicles. Most of the SAR techniques are based on monostatic technology, where both transmitter and receiver are onboard the same air- or spaceborne platform. In the last two decades, intensive studies have been carried out on bistatic and multistatic radar observation, including testing of the bistatic SAR concept [5], [6]. The main feature of the bistatic radar system is the physical separation between the transmitter and the receiver. The main advantage of such a configuration is that a target can be observed from different bistatic angles, providing more information about the target. A further step in bistatic radar development is to use transmitters of opportunity for scene illumination instead of dedicated and easily detected SAR transmitters. This leads directly to the idea of passive SAR imaging.

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