This paper reports on the application of radar satellite data and Persistent Scatterer Inter- ferometry (PS-InSAR) techniques for the detection of ground deformation in the semi-arid loess region of Lanzhou, northwestern China. Compared with Synthetic Aperture Radar Interferometry (InSAR), PS- InSAR overcomes the problems of temporal and geometric de-correlation and atmospheric heteroge- neities by identifying persistent radar targets (PS) in a series of interferograms. The SPINUA algorithm was used to process 40 ENVISAT ASAR images for the study period 2003-2010. The analysis resulted in the identification of over 140000 PS in the greater Lanzhou area covering some 300 km2. The spatial distribution of moving radar targets was checked during a field campaign and highlights the range of ground instability problems that the Lanzhou area faces as urban expansion continues to accelerate. The PS-InSAR application detected ground deformations with rates up to 10mma-1; it resulted in the detection of previously unknown unstable slopes and two areas of subsidence.
Ground instability detection using PS-InSAR in Lanzhou, China
Wasowski J;Bovenga F;
2014
Abstract
This paper reports on the application of radar satellite data and Persistent Scatterer Inter- ferometry (PS-InSAR) techniques for the detection of ground deformation in the semi-arid loess region of Lanzhou, northwestern China. Compared with Synthetic Aperture Radar Interferometry (InSAR), PS- InSAR overcomes the problems of temporal and geometric de-correlation and atmospheric heteroge- neities by identifying persistent radar targets (PS) in a series of interferograms. The SPINUA algorithm was used to process 40 ENVISAT ASAR images for the study period 2003-2010. The analysis resulted in the identification of over 140000 PS in the greater Lanzhou area covering some 300 km2. The spatial distribution of moving radar targets was checked during a field campaign and highlights the range of ground instability problems that the Lanzhou area faces as urban expansion continues to accelerate. The PS-InSAR application detected ground deformations with rates up to 10mma-1; it resulted in the detection of previously unknown unstable slopes and two areas of subsidence.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.