Treating Tropospheric Phase Delay in Large-scale Sentinel-1 Stacks to Analyze Land Subsidence

IF 2.1 4区 地球科学 Q3 IMAGING SCIENCE & PHOTOGRAPHIC TECHNOLOGY PFG-Journal of Photogrammetry Remote Sensing and Geoinformation Science Pub Date : 2024-08-02 DOI:10.1007/s41064-024-00304-z
Mahmud Haghshenas Haghighi, Mahdi Motagh
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Abstract

Variations in the tropospheric phase delay pose a primary challenge to achieving precise displacement measurements in Interferometric Synthetic Aperture Radar (InSAR) analysis. This study presents a cluster-based empirical tropospheric phase correction approach to analyze land subsidence rates from large-scale Sentinel‑1 data stacks. Our method identifies the optimum number of clusters in individual interferograms for K‑means clustering, and segments extensive interferograms into areas with consistent tropospheric phase delay behaviors. It then performs tropospheric phase correction based on empirical topography-phase correlation, addressing stratified and broad-scale tropospheric phase delays. Applied to a six-year data stack along a 1000-km track in Iran, we demonstrate that this approach enhances interferogram quality by reducing the standard deviation by 50% and lowering the semivariance of the interferograms to 20 cm2 at distances up to 800 km in 97% of the interferograms. Additionally, the corrected time series of deformation shows a 40% reduction in the root mean square of residuals at the most severely deformed points. By analyzing the corrected interferograms, we show that our method improves the efficiency of country-scale InSAR surveys to detect and quantify present-day land subsidence in Iran, which is essential for groundwater management and sustainable water resource planning.

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处理大规模哨兵-1 叠加数据中的对流层相位延迟以分析地面沉降
对流层相位延迟的变化是干涉合成孔径雷达(InSAR)分析中实现精确位移测量的主要挑战。本研究提出了一种基于集群的对流层经验相位校正方法,用于分析来自大规模哨兵-1 数据集的土地沉降率。我们的方法在单个干涉图中确定 K-means 聚类的最佳簇数,并将大范围干涉图分割成具有一致对流层相位延迟行为的区域。然后根据经验地形-相位相关性进行对流层相位校正,解决分层和大尺度对流层相位延迟问题。我们将这种方法应用于伊朗 1000 公里轨道上的六年数据堆栈,结果表明,这种方法提高了干涉图的质量,将标准偏差降低了 50%,在距离达 800 公里的干涉图中,97%的干涉图的半方差降低到 20 平方厘米。此外,校正后的变形时间序列显示,变形最严重点的残差均方根降低了 40%。通过分析校正后的干涉图,我们发现我们的方法提高了国家尺度 InSAR 勘测的效率,可用于探测和量化伊朗现今的土地沉降,这对地下水管理和可持续水资源规划至关重要。
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来源期刊
CiteScore
8.20
自引率
2.40%
发文量
38
期刊介绍: PFG is an international scholarly journal covering the progress and application of photogrammetric methods, remote sensing technology and the interconnected field of geoinformation science. It places special editorial emphasis on the communication of new methodologies in data acquisition and new approaches to optimized processing and interpretation of all types of data which were acquired by photogrammetric methods, remote sensing, image processing and the computer-aided interpretation of such data in general. The journal hence addresses both researchers and students of these disciplines at academic institutions and universities as well as the downstream users in both the private sector and public administration. Founded in 1926 under the former name Bildmessung und Luftbildwesen, PFG is worldwide the oldest journal on photogrammetry. It is the official journal of the German Society for Photogrammetry, Remote Sensing and Geoinformation (DGPF).
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