Monitoring of Residual Subsidence in Old Goafs Based on Ultrashort-Baseline InSAR Technology

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Authors

  • School of Geography & Geomatics and Urban-Rural Planning, Jiangsu Normal University, No. 101, Shanghai road, 221116, Xuzhou ,CN
  • School of Geography & Geomatics and Urban-Rural Planning, Jiangsu Normal University, No. 101, Shanghai road, 221116, Xuzhou ,CN

Keywords:

Old Goaf, Residual Subsidence, Ultrashort Baseline, InSAR, Subsidence Monitoring.

Abstract

When applying the differential interferometric synthetic aperture radar (D-InSAR) technology to high-resolution SAR data, an external digital elevation model (DEM) with comparable resolution is usually not available for removing topography-related phase component for the purpose of deformation extraction. To avoid the problem due to insufficient DEM resolution, a DEM-free InSAR approach based on ultrashort spatial baselines (USB) is introduced here, capable of overcoming DEM limitations of conventional differential InSAR technique. We analyzed the principle of selection of USB interferometric pairs, and briefed permanent scatter (PS) pixel phase modeling and parameter estimation with respect to USB technology. This method was applied to the subsidence monitoring in three old goafs in Yulin mining, Shaanxi. The corresponding law of subsidence obtained was used to establish the empirical relation between circulating peak of subsidence velocity and mining thickness as well as between subsidence velocity cycle and ratio of mining depth to mining thickness. The experiment results provide basis for predicting and evaluating the residual subsidence of old goafs.

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Published

2022-10-19

How to Cite

Bingqian, C., & Yijie, L. (2022). Monitoring of Residual Subsidence in Old Goafs Based on Ultrashort-Baseline InSAR Technology. Journal of Mines, Metals and Fuels, 64(12), 676–683. Retrieved from https://informaticsjournals.co.in/index.php/jmmf/article/view/31634

 

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