Accurate Deformation Retrieval of the 2023 Turkey–Syria Earthquakes Using Multi-Track InSAR Data and a Spatio-Temporal Correlation Analysis with the ICA Method

Multi-track synthetic aperture radar interferometry (InSAR) provides a good approach for the monitoring of long-term multi-dimensional earthquake deformation, including pre-, co-, and post-seismic data. However, the removal of atmospheric errors in both single- and multi-track InSAR data presents si...

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Bibliographic Details
Published inRemote sensing (Basel, Switzerland) Vol. 16; no. 17; p. 3139
Main Authors Liu, Yuhao, Wu, Songbo, Zhang, Bochen, Xiong, Siting, Wang, Chisheng
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2024
Subjects
2023 Turkey–Syria earthquakes
Correlation analysis
Data analysis
Deformation effects
Earthquakes
Eigenvalues
Global positioning systems
GPS
Independent component analysis
Interferometric synthetic aperture radar
Interferometry
Methods
Monitoring
Retrieval
Satellite navigation systems
Seismic activity
Signal processing
Spatial data
spatio-temporal correlation analysis
Spatiotemporal data
Statistical analysis
Time series
time series two-dimensional deformation
Turkey
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Summary:Multi-track synthetic aperture radar interferometry (InSAR) provides a good approach for the monitoring of long-term multi-dimensional earthquake deformation, including pre-, co-, and post-seismic data. However, the removal of atmospheric errors in both single- and multi-track InSAR data presents significant challenges. In this paper, a method of spatio-temporal correlation analysis using independent component analysis (ICA) is proposed, which can extract multi-track deformation components for the accurate retrieval of earthquake deformation time series. Sentinel-1 data covering the double earthquakes in Turkey and Syria in 2023 are used to demonstrate the effectiveness of the proposed method. The results show that co-seismic displacement in the east–west and up–down directions ranged from −114.7 cm to 82.8 cm and from −87.0 cm to 63.9 cm, respectively. Additionally, the deformation rates during the monitoring period ranged from −137.9 cm/year to 123.3 cm/year in the east–west direction and from −51.8 cm/year to 45.7 cm/year in the up–down direction. A comparative validation experiment was conducted using three GPS stations. Compared with the results of the original MSBAS method, the proposed method provides results that are smoother and closer to those of the GPS data, and the average optimization efficiency is 43.08% higher. The experiments demonstrated that the proposed method could provide accurate two-dimensional deformation time series for studying the pre-, co-, and post-earthquake events of the 2023 Turkey–Syria Earthquakes.
ISSN:2072-4292
DOI:10.3390/rs16173139