Abstract
Abstract. Underground coal exploitation has its reflection in ground movements such as subsidence, sinking or shaking. These cause buildings and infrastructure damage, therefore it is important to measure the magnitude of deformation. Last decades, Differential Interferometric Synthetic Aperture Radar (DInSAR) captured considerable attention as a tool for deformation monitoring. The results of conventional DInSAR, which utilizes two SAR images, are degraded due to atmospheric, topographic and orbital errors. To overcome these limitations, various stacking-based methods have been introduced. Therefore, the goal of presented study is to compare Persistent Scatterer Interferometry (PSI) as stacking-based method with classical DInSAR for monitoring of subsidence caused by underground coal exploitation. Deformations in the areas of active mining exploitation are characterised typically by rapid non-linear movement. The comparison has been performed for the area of active exploitation in Rydułtowy mine located in Upper Silesian Coal Basin (USCB) in Poland. Results from two separate PSI and DInSAR processing portray similar deformation pattern over the study area. Unfortunately, due to the temporal decorrelation, PSI clearly demonstrate smaller information coverage in respect to DInSAR results. Additionally, due to the applied linear deformation model, PSI failed in displacement estimation with magnitude higher than 12 cm. In contrast, DInSAR thanks 6-day temporal baseline and no assumption for a deformation model, was able to capture the maximum magnitude of subsidence reaching 86 cm/year. However, these results are affected by atmospheric artefacts which in presented case study can reach even 14 cm/year. To achieve few cm level of accuracy and to estimate high deformation magnitude such as in presented study case (1m/year), integrated use of both InSAR techniques seems to be the reasonable solution.
Highlights
Poland is one of the biggest coal producer in Europe
The results of conventional Differential Interferometric Synthetic Aperture Radar (DInSAR), which utilizes two SAR images, are affected by atmospheric, topographic and orbital errors. To reduce these adverse effects various stacking-based methods have been introduced such as Persistent Scatterer Interferometry (PSI)
Due to the applied linear deformation model, PSI failed in the displacement estimation with magnitude higher than 12 cm/year
Summary
Poland is one of the biggest coal producer in Europe. Upper Silesian Coal Basin (USCB) which is located in Southern Poland covers an area of almost 6000km (Przyłucka et al, 2016). Coal exploitation performed underground has its consequence in ground movements such as subsidence, sinking or shaking (Mutke et al, 2019) This ground deformation often results in buildings and infrastructure destruction (Przyłucka et al, 2019). Interferograms generated by SAR acquisitions with C-band or X-band are very sensitive to the temporal decorrelation This significantly reduces the possibility of InSAR applications in rural areas. All SAR images can be utilized for the interferograms generation even if the baseline between these two images is longer than a critical baseline This approach makes it possible to achieve sub-meter digital elevation model (DEM) precision and millimetres level of deformation measurements (Ferretti et al, 2001). The analysis is performed at the full spatial resolution and is focused on pixels containing a single dominant scatterer (Pepe and Calò, 2017)
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