A novel framework for landslide displacement prediction using MT-InSAR and machine learning techniques

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Chao Zhou
  • Ying Cao
  • Lulu Gan
  • Yue Wang
  • Mahdi Motagh
  • Sigrid Roessner
  • Xie Hu
  • Kunlong Yin

Research Organisations

External Research Organisations

  • China University of Geosciences
  • Helmholtz Centre Potsdam - German Research Centre for Geosciences (GFZ)
  • Peking University
View graph of relations

Details

Original languageEnglish
Article number107497
Number of pages14
JournalEngineering geology
Volume334
Early online date8 Apr 2024
Publication statusPublished - May 2024

Abstract

The prediction of landslide deformation is an important part of landslide early warning systems. Displacement prediction based on geotechnical in-situ monitoring performs well, but its high costs and spatial limitations hinder frequent use within large areas. Here, we propose a novel physically-based and cost-effective landslide displacement prediction framework using the combination of Multi-Temporal Interferometric Synthetic Aperture Radar (MT-InSAR) and machine learning techniques. We first extract displacement time series for the landslide from spaceborne Copernicus Sentinel-1A SAR imagery by MT-InSAR. Using wavelet transform, we then decompose the nonlinear displacement time series into trend terms, periodic terms, and noises. The advanced machine learning method of Gated Recurrent Units (GRU) is utilized to predict the trend and periodic displacements, respectively. The modeling inputs for trend and periodic displacement predictions are determined by analyzing their corresponding influencing factors. The total displacements are finally predicted by summing the predicted displacements of trend and periodic items. The Shuping and Muyubao landslides, identified as seepage-driven and buoyancy-driven, respectively, in the Three Gorges Reservoir area in China are selected as case studies to evaluate the performance of our methodology. The prediction results demonstrate that machine learning algorithms can accurately establish the nonlinear relationship between the landslide deformation and its triggers. GRU outperforms the algorithms of Long Short-Term Memory networks and Kernel-based Extreme Learning Machine, and the Adam algorithm can effectively optimize the model hyperparameters. The root mean square error and mean absolute percentage error are 3.817 and 0.022 in Shuping landslide, and 5.145 and 0.020 in Muyubao landslide, respectively. By integrating the advantages of MT-InSAR and machine learning techniques, our proposed prediction framework, considering the physics principles behind landslide deformation, can predict landslide displacement cost-effectively within large areas.

Keywords

    Deformation characteristics, Landslide displacement prediction, Machine learning, MT-InSAR

ASJC Scopus subject areas

Cite this

A novel framework for landslide displacement prediction using MT-InSAR and machine learning techniques. / Zhou, Chao; Cao, Ying; Gan, Lulu et al.
In: Engineering geology, Vol. 334, 107497, 05.2024.

Research output: Contribution to journalArticleResearchpeer review

Zhou, C., Cao, Y., Gan, L., Wang, Y., Motagh, M., Roessner, S., Hu, X., & Yin, K. (2024). A novel framework for landslide displacement prediction using MT-InSAR and machine learning techniques. Engineering geology, 334, Article 107497. https://doi.org/10.1016/j.enggeo.2024.107497
Zhou C, Cao Y, Gan L, Wang Y, Motagh M, Roessner S et al. A novel framework for landslide displacement prediction using MT-InSAR and machine learning techniques. Engineering geology. 2024 May;334:107497. Epub 2024 Apr 8. doi: 10.1016/j.enggeo.2024.107497
Download
@article{bf0a34725d8249468b9a8b4c3b6851dd,
title = "A novel framework for landslide displacement prediction using MT-InSAR and machine learning techniques",
abstract = "The prediction of landslide deformation is an important part of landslide early warning systems. Displacement prediction based on geotechnical in-situ monitoring performs well, but its high costs and spatial limitations hinder frequent use within large areas. Here, we propose a novel physically-based and cost-effective landslide displacement prediction framework using the combination of Multi-Temporal Interferometric Synthetic Aperture Radar (MT-InSAR) and machine learning techniques. We first extract displacement time series for the landslide from spaceborne Copernicus Sentinel-1A SAR imagery by MT-InSAR. Using wavelet transform, we then decompose the nonlinear displacement time series into trend terms, periodic terms, and noises. The advanced machine learning method of Gated Recurrent Units (GRU) is utilized to predict the trend and periodic displacements, respectively. The modeling inputs for trend and periodic displacement predictions are determined by analyzing their corresponding influencing factors. The total displacements are finally predicted by summing the predicted displacements of trend and periodic items. The Shuping and Muyubao landslides, identified as seepage-driven and buoyancy-driven, respectively, in the Three Gorges Reservoir area in China are selected as case studies to evaluate the performance of our methodology. The prediction results demonstrate that machine learning algorithms can accurately establish the nonlinear relationship between the landslide deformation and its triggers. GRU outperforms the algorithms of Long Short-Term Memory networks and Kernel-based Extreme Learning Machine, and the Adam algorithm can effectively optimize the model hyperparameters. The root mean square error and mean absolute percentage error are 3.817 and 0.022 in Shuping landslide, and 5.145 and 0.020 in Muyubao landslide, respectively. By integrating the advantages of MT-InSAR and machine learning techniques, our proposed prediction framework, considering the physics principles behind landslide deformation, can predict landslide displacement cost-effectively within large areas.",
keywords = "Deformation characteristics, Landslide displacement prediction, Machine learning, MT-InSAR",
author = "Chao Zhou and Ying Cao and Lulu Gan and Yue Wang and Mahdi Motagh and Sigrid Roessner and Xie Hu and Kunlong Yin",
note = "Funding Information: This research is funded by the National Natural Science Foundation of China (No. 42371094 and No. 41702330 ) and Key Research and Development Program of Hubei Province (No. 2021BCA219 ). We would like to appreciate the editor and two referees for their comments which significantly improves this paper. The first author would like to thank the China Scholarship Council for funding his research at the German Research Centre for Geosciences .",
year = "2024",
month = may,
doi = "10.1016/j.enggeo.2024.107497",
language = "English",
volume = "334",
journal = "Engineering geology",
issn = "0013-7952",
publisher = "Elsevier",

}

Download

TY - JOUR

T1 - A novel framework for landslide displacement prediction using MT-InSAR and machine learning techniques

AU - Zhou, Chao

AU - Cao, Ying

AU - Gan, Lulu

AU - Wang, Yue

AU - Motagh, Mahdi

AU - Roessner, Sigrid

AU - Hu, Xie

AU - Yin, Kunlong

N1 - Funding Information: This research is funded by the National Natural Science Foundation of China (No. 42371094 and No. 41702330 ) and Key Research and Development Program of Hubei Province (No. 2021BCA219 ). We would like to appreciate the editor and two referees for their comments which significantly improves this paper. The first author would like to thank the China Scholarship Council for funding his research at the German Research Centre for Geosciences .

PY - 2024/5

Y1 - 2024/5

N2 - The prediction of landslide deformation is an important part of landslide early warning systems. Displacement prediction based on geotechnical in-situ monitoring performs well, but its high costs and spatial limitations hinder frequent use within large areas. Here, we propose a novel physically-based and cost-effective landslide displacement prediction framework using the combination of Multi-Temporal Interferometric Synthetic Aperture Radar (MT-InSAR) and machine learning techniques. We first extract displacement time series for the landslide from spaceborne Copernicus Sentinel-1A SAR imagery by MT-InSAR. Using wavelet transform, we then decompose the nonlinear displacement time series into trend terms, periodic terms, and noises. The advanced machine learning method of Gated Recurrent Units (GRU) is utilized to predict the trend and periodic displacements, respectively. The modeling inputs for trend and periodic displacement predictions are determined by analyzing their corresponding influencing factors. The total displacements are finally predicted by summing the predicted displacements of trend and periodic items. The Shuping and Muyubao landslides, identified as seepage-driven and buoyancy-driven, respectively, in the Three Gorges Reservoir area in China are selected as case studies to evaluate the performance of our methodology. The prediction results demonstrate that machine learning algorithms can accurately establish the nonlinear relationship between the landslide deformation and its triggers. GRU outperforms the algorithms of Long Short-Term Memory networks and Kernel-based Extreme Learning Machine, and the Adam algorithm can effectively optimize the model hyperparameters. The root mean square error and mean absolute percentage error are 3.817 and 0.022 in Shuping landslide, and 5.145 and 0.020 in Muyubao landslide, respectively. By integrating the advantages of MT-InSAR and machine learning techniques, our proposed prediction framework, considering the physics principles behind landslide deformation, can predict landslide displacement cost-effectively within large areas.

AB - The prediction of landslide deformation is an important part of landslide early warning systems. Displacement prediction based on geotechnical in-situ monitoring performs well, but its high costs and spatial limitations hinder frequent use within large areas. Here, we propose a novel physically-based and cost-effective landslide displacement prediction framework using the combination of Multi-Temporal Interferometric Synthetic Aperture Radar (MT-InSAR) and machine learning techniques. We first extract displacement time series for the landslide from spaceborne Copernicus Sentinel-1A SAR imagery by MT-InSAR. Using wavelet transform, we then decompose the nonlinear displacement time series into trend terms, periodic terms, and noises. The advanced machine learning method of Gated Recurrent Units (GRU) is utilized to predict the trend and periodic displacements, respectively. The modeling inputs for trend and periodic displacement predictions are determined by analyzing their corresponding influencing factors. The total displacements are finally predicted by summing the predicted displacements of trend and periodic items. The Shuping and Muyubao landslides, identified as seepage-driven and buoyancy-driven, respectively, in the Three Gorges Reservoir area in China are selected as case studies to evaluate the performance of our methodology. The prediction results demonstrate that machine learning algorithms can accurately establish the nonlinear relationship between the landslide deformation and its triggers. GRU outperforms the algorithms of Long Short-Term Memory networks and Kernel-based Extreme Learning Machine, and the Adam algorithm can effectively optimize the model hyperparameters. The root mean square error and mean absolute percentage error are 3.817 and 0.022 in Shuping landslide, and 5.145 and 0.020 in Muyubao landslide, respectively. By integrating the advantages of MT-InSAR and machine learning techniques, our proposed prediction framework, considering the physics principles behind landslide deformation, can predict landslide displacement cost-effectively within large areas.

KW - Deformation characteristics

KW - Landslide displacement prediction

KW - Machine learning

KW - MT-InSAR

UR - http://www.scopus.com/inward/record.url?scp=85190495478&partnerID=8YFLogxK

U2 - 10.1016/j.enggeo.2024.107497

DO - 10.1016/j.enggeo.2024.107497

M3 - Article

AN - SCOPUS:85190495478

VL - 334

JO - Engineering geology

JF - Engineering geology

SN - 0013-7952

M1 - 107497

ER -