Fusion of InSAR and GWO-LSTM for deformation monitoring and prediction of high and steep mountains: a case study of a slope in the Jinsha River basin

doi:10.13474/j.cnki.11-2246.2024.0909

Bulletin of Surveying and Mapping ›› 2024, Vol. 0 ›› Issue (9): 44-49.doi: 10.13474/j.cnki.11-2246.2024.0909

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Fusion of InSAR and GWO-LSTM for deformation monitoring and prediction of high and steep mountains: a case study of a slope in the Jinsha River basin

PENG Xiang¹, GAN Shu^1,2, YUAN Xiping^2,3, ZHU Zhifu¹, LI Xuan¹, GONG Weizhen¹

1. Faculty of Land Resources Engineering, Kunming University of Science and Technology, Kunming 650093, China;
2. Application Engineerimg Research Center of Plaleau and Mountainous Spatial Information Surveying and Mapping Technology in Yunnan Universities, Kunming 650093, China;
3. Key Laloratory of Cloud Data Processing and Application of Mountain Scenic Spot in Yunnan Universities, West Yunnan University of Applied Technology, Dali 671006, China

Received:2024-01-02 Published:2024-10-09

Abstract

Abstract: Due to the fact that the downstream of the Wudongde hydropower station is located in the Jinsha River basin, the flood discharge of the hydropower station will cause changes in the water level in the downstream area and frequent geological activities near the fault zone, thereby changing the stability of the slopes around the basin. It is highly prone to landslide disasters and causing river blockage. In order to gain the understanding of the slope conditions in high and steep mountainous areas, this experiment utilizes 81 Sentinel-A images from January 2021 to October 2023, and obtains surface deformation characteristics using SBAS-InSAR technology. By combining deformation rate maps and remote sensing images, potential landslide risk areas are identified. A1, A2, and A4 are selected as typical areas and analyzed through cumulative temporal deformation. A LSTM neural network settlement prediction model is constructed, and then the GWO algorithm for hyperparameter optimization is used. The settlement data obtained from the final point selection is divided into a training set and a testing set, and compared with the accuracy of the traditional prediction model SVR. The results show that the GWO-LSTM model has high accuracy in predicting landslide deformation in complex mountainous areas. Among the 9 test points, the maximum mean absolute error is 1.080 8 mm and the maximum root mean square error is 1.194 2 mm. This paper provides a theoretical basis for landslide disaster warning and management.

Key words: SABS-InSAR, landslide identification, GWO, LSTM memory network

CLC Number:

P237

PENG Xiang, GAN Shu, YUAN Xiping, ZHU Zhifu, LI Xuan, GONG Weizhen. Fusion of InSAR and GWO-LSTM for deformation monitoring and prediction of high and steep mountains: a case study of a slope in the Jinsha River basin[J]. Bulletin of Surveying and Mapping, 2024, 0(9): 44-49.

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Fusion of InSAR and GWO-LSTM for deformation monitoring and prediction of high and steep mountains: a case study of a slope in the Jinsha River basin

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