High-precision positioning of radar scatterers

Dheenathayalan, Prabu; Small, David; Schubert, Adrian; Hanssen, Ramon F.

doi:10.1007/s00190-015-0883-4

Cited by 46 publications

(57 citation statements)

References 26 publications

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“…Previous validation experiments using artificial targets have found that the accuracy of displacement estimates from PSInSAR analysis is at the millimetre level [15,16]. Recent advances have also seen the development of algorithms for absolute positioning of SAR scatterers using stereo SAR images of targets acquired using multiple imaging geometries [17,18]. Common to all these applications is the need for an artificial target with a geodetically known position that has been designed to have a bright and stable response in SAR imagery.…”

Section: Introductionmentioning

confidence: 99%

On the Design of Radar Corner Reflectors for Deformation Monitoring in Multi-Frequency InSAR

Garthwaite

2017

Remote Sensing

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Trihedral corner reflectors are being increasingly used as point targets in deformation monitoring studies using interferometric synthetic aperture radar (InSAR) techniques. The frequency and size dependence of the corner reflector Radar Cross Section (RCS) means that no single design can perform equally in all the possible imaging modes and radar frequencies available on the currently orbiting Synthetic Aperture Radar (SAR) satellites. Therefore, either a corner reflector design tailored to a specific data type or a compromise design for multiple data types is required. In this paper, I outline the practical and theoretical considerations that need to be made when designing appropriate radar targets, with a focus on supporting multi-frequency SAR data. These considerations are tested by performing field experiments on targets of different size using SAR images from TerraSAR-X, COSMO-SkyMed and RADARSAT-2. Phase noise behaviour in SAR images can be estimated by measuring the Signal-to-Clutter ratio (SCR) in individual SAR images. The measured SCR of a point target is dependent on its RCS performance and the influence of clutter near to the deployed target. The SCR is used as a metric to estimate the expected InSAR displacement error incurred by the design of each target and to validate these observations against theoretical expectations. I find that triangular trihedral corner reflectors as small as 1 m in dimension can achieve a displacement error magnitude of a tenth of a millimetre or less in medium-resolution X-band data. Much larger corner reflectors (2.5 m or greater) are required to achieve the same displacement error magnitude in medium-resolution C-band data. Compromise designs should aim to satisfy the requirements of the lowest SAR frequency to be used, providing that these targets will not saturate the sensor of the highest frequency to be used. Finally, accurate boresight alignment of the corner reflector can be critical to the overall target performance. Alignment accuracies better than 4 • in azimuth and elevation will incur a minimal impact on the displacement error in X and C-band data.

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Section: Introductionmentioning

confidence: 99%

On the Design of Radar Corner Reflectors for Deformation Monitoring in Multi-Frequency InSAR

Garthwaite

2017

Remote Sensing

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“…The positioning precision is 1–2 m for C‐band data and less than 1 m for X‐band data (Dheenathayalan, Cuenca, Hoogeboom, & Hanssen, ). Using the exact PS locations, reflections from the ground can be separated from those originating from higher level objects, which may show a different deformation behaviour (Dheenathayalan, Small, Schubert, & Hanssen, ). Georeferencing is thus of high importance in the analysis of the results, in particular when the deformation is localised (Chang & Hanssen, ).…”

Section: Characteristics Applicability and Qualitymentioning

confidence: 99%

“…Moreover, recent approaches on estimating deformation in areas with low coherence, and in the absence of sufficient PS appear to be promising (Morishita & Hanssen, 2015a, 2015b. A low PS density can also be overcome by installing in-situ devices, that is, corner reflectors or active transponders, which provide a strong signal in the SAR images resulting in adequate deformation estimates (Dheenathayalan et al, 2016;Mahapatra et al, 2014;Sarabandi & Chiu, 1996).…”

Section: Applicabilitymentioning

confidence: 99%

Applicability of satellite radar imaging to monitor the conditions of levees

Özer

Leijen

Jonkman

et al. 2018

J Flood Risk Management

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Levees are critical systems in safeguarding an area against catastrophic flooding events with potential fatalities and economic losses. Current monitoring methods of levees highly rely on expert judgement, resulting in infrequent and subjective assessments of their status. Satellite radar imaging, in particular using interferometry (InSAR), holds a large potential to monitor the condition of levees with millimetre‐level precision, anywhere on the planet. However, for levee management, the usability of the technique requires significant radar expert knowledge. Here, we provide a comprehensive overview of the state of the art in using time‐series InSAR for systematic levee deformation monitoring. We explore its use to complement existing approaches for assessing levee deformation and failure investigations in a fast, systematic, and cost‐effective way. The applicability of imaging radar satellites is discussed, supported by case studies on levee monitoring in the Netherlands. We elaborate on the technical aspects with respect to levee monitoring using SAR technology, such as estimating deformation in different directions, satellite characteristics, precision, and reliability. We conclude that InSAR is becoming an operational deformation monitoring system, which allows for the detection, tracking, and analysis of irregularities on levee sections with increased efficiency and quality, thus contributing to improved risk management.

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“…Millimetre per year accuracy can be achieved in deformation trend estimation. Unfortunately the source of the deformation signal is, in general, less accurately known: geolocation estimates of PS-InSAR are known with metres precision at best, depending on the sensor (Dheenathayalan et al, 2016).…”

Section: Ps-insar Deformation Monitoringmentioning

confidence: 99%

Massive Linking of Ps-Insar Deformations to a National Airborne Laser Point Cloud

Natijne

Lindenbergh

Hanssen

2018

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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Build on soft soil, close to sea level the Netherlands is at high risk for the effects of subsidence and deformation. Interferometric Synthetic Aperture Radar (InSAR) is successfully used to monitor the deformation trends at millimetre level. Unfortunately the InSAR deformation trends suffer from poor geolocation estimates, limiting the ability to link deformation behaviour to objects, such as buildings, streets or bridges. A nationwide, high resolution, airborne LiDAR point cloud is available in the Netherlands. Although the position accuracy of this LiDAR point cloud is to low for deformation estimates, linking the InSAR location to the geometries outlined by the LiDAR point can improve the geolocation estimates of the InSAR trends. To our knowledge no such integration is available as of yet. In this article we outline methods to link deformation estimates to the LiDAR point cloud and give an outlook of possible improvements. As a test we link 3.1 million TerraSAR-X InSAR Persistent Scatterers to 3 billion LiDAR points, covering the city of Delft and surroundings.

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High-precision positioning of radar scatterers

Cited by 46 publications

References 26 publications

On the Design of Radar Corner Reflectors for Deformation Monitoring in Multi-Frequency InSAR

On the Design of Radar Corner Reflectors for Deformation Monitoring in Multi-Frequency InSAR

Applicability of satellite radar imaging to monitor the conditions of levees

Massive Linking of Ps-Insar Deformations to a National Airborne Laser Point Cloud

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