InSAR validation based on GNSS measurements in Bucharest

ABSTRACT

This research aims to complex validate radar displacement products over Bucharest based on Global Navigation Satellite System or GNSS. Validation was represented by the comparison of the recent TerraSAR-X (TSX) displacement results with field GNSS data. For this purpose, 24 and 27 high-resolution images acquired from the TSX satellite between 2011 and 2014 were processed by Permanent Scatterer Inteferometry (PSI) and Small BASeline Subset (SBAS) – interferometric techniques using synthetic aperture radar (SAR) images. The images were selected from a larger pool of SAR images, after consulting weather databases, which helped eliminate the images acquired under adverse weather conditions. GNSS locations were cross-checked on high-resolution optical images and 21 ground points (including three permanent stations) were selected. All these points were (1) characterized by high coherence on radar images; (2) were on the ground; (3) were situated in large vacant spaces; and (4) far away from radar obstacles such as trees. A major challenge in achieving the research goal was to overcome the lack of permanent stations at the ground level within the area of Bucharest. Instead of permanent stations, our team designed and installed forced centring systems that remained stable over time, eliminating the instalment errors of GNSS receivers. The line-of-site (LOS) components derived from GNSS data have been compared with those of the SAR scatterers closest to the GNSS markers (never coinciding). For each location, the vertical reading was projected in the LOS of the SAR sensor. These readings were compared with the displacement values determined at the locations of permanent scatterers (PSs) within 100 m from the GNSS nodes, by eliminating all scatterers on buildings. The comparison has shown a good agreement.

Acknowledgements

This research was financed by grant 78/29 November 2013 of the Romanian Space Agency and grant 285/2011,budgeted by the Executive Unit for Financing the Higher Education and University Researches, both having Prof. Armaş as principal investigator. TSX data were provided via DLR Proposal LAN 1444. We would like to thank Dr Eng. Marius Necşoiu for support in processing InSAR data.

Disclosure statement

No potential conflict of interest was reported by the authors.

Additional information

Funding

This research was financed by grant 78/29 November 2013 of the Romanian Space Agency and grant 285/2011, budgeted by the Executive Unit for Financing the Higher Education and University Researches, both having Prof Armaş as principal investigator. TSX data were provided via DLR Proposal LAN 1444.