干涉合成孔径雷达
聚类分析
变形(气象学)
背景(考古学)
系列(地层学)
运动学
理论(学习稳定性)
人工智能
大地测量学
地质学
变形监测
计算机科学
模式识别(心理学)
遥感
机器学习
合成孔径雷达
经典力学
海洋学
物理
古生物学
作者
Mengshi Yang,Menghua Li,Cheng Huang,Ruisi Zhang,Rui Liu
出处
期刊:Remote Sensing
[Multidisciplinary Digital Publishing Institute]
日期:2024-04-13
卷期号:16 (8): 1375-1375
被引量:5
摘要
As a city undergoes large-scale construction and expansion, there is an urgent need to monitor the stability of the ground and infrastructure. The time-series InSAR technique is an effective tool for measuring surface displacements. However, interpreting these displacements in a built environment, where observed displacements consist of mixed signals, poses a challenge. This study uses principal component analysis (PCA) and the k-means clustering method for exploring deformation series within an unsupervised learning context. The PCA method extracts the dominant components in deformation series, whereas the clustering method identifies similar deformation series. This method was tested on Kunming City (KMC) using C-band Sentinel-1, X-band TerraSAR-X, and L-band ALOS-2 PALSAR-2 data acquired between 2017 to 2022. The experiment demonstrated that the suggested unsupervised learning approach can group PS points with similar kinematic characteristics. Five types of deformation kinematic characteristics were discovered in the three SAR datasets: upward, slight upward, stability, slight downward, and downward. According to the results, less than 20% of points exhibit significant motion trends, whereas 50% show small velocity values but still demonstrate movement trends. The remaining 30% are relatively stable. Similar clustering results were obtained from the three datasets using unsupervised methods, highlighting the effectiveness of identifying spatial–temporal patterns over the study area. Moreover, It was found that clustering based on kinematic characteristics enhances the interpretation of InSAR deformation, particularly for points with small deformation velocities. Finally, the significance of PCA decomposition in interpreting InSAR deformation was discussed, as it can better represent series with noise, enabling their accurate identification.
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