基于一阶可靠度方法的区域滑坡易发性概率评估与QGIS平台实现

doi:10.3724/1000-6915.jrme.2025.0281

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摘要为提升区域滑坡风险识别的科学性与预测精度，针对地震诱发的浅层滑坡，考虑岩土体参数的不确定性，基于改进的一阶可靠度法（FORM）构建一种区域滑坡易发性概率评估框架。通过耦合拟静力方法，建立地震影响下无限长边坡物理模型，并将关键土体参数视为随机变量，量化不确定性对滑坡失效概率的影响。进一步地，基于Python语言开发了QGIS-FORM插件，以失效概率（）和安全系数（FOS）为指标，实现了区域滑坡易发性分布图的自动化生成。以马尔康地震滑坡事件为例，从地形坡度、地面峰值加速度、地质岩性3个方面进行了关键参数分析，将FORM与均值一次二阶矩法（MFOSM）进行了对比验证，通过受试者工作特征曲线（ROC）和平衡准确率（BA）分别评价了不同尺度缓冲区和变异系数（COV）条件下和FOS的预测性能。结果显示：相对于MFOSM，FORM在处理复杂边坡的非线性问题时更具优势，AUC值提高了5.5%。在不同尺度的缓冲区，的AUC值分别为82.9%，84.1%，85.0%，均优于FOS。BA曲线表明，随着COV增加，FORM方法的阈值分别为0.08，0.2，0.27，对应最大BA值均为0.704，表明COV仅影响的最佳阈值，而不影响模型最优预测性能。FORM方法能有效考虑输入参数的不确定性，提供更稳定、细致的滑坡风险区划结果，为滑坡风险管理提供了更具科学性的可视化分析工具。

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	佟斌1
	崔红志2
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关键词 ：边坡工程, 边坡稳定性, 概率分析, 一阶可靠度方法, 滑坡易发性, QGIS插件

Abstract：

To improve the scientific basis and accuracy of regional landslide risk identification, the uncertainty of geotechnical parameters in shallow landslides triggered by earthquakes is considered. An improved First Order Reliability Method (FORM) is used to develop a probabilistic framework for regional landslide susceptibility assessment. A physical model of an infinite slope under seismic loading is constructed using a pseudo-static approach, where key soil parameters are treated as random variables to quantify the impact of uncertainty on landslide failure probability. A QGIS plugin, QGIS-FORM, is developed in Python to automate the generation of regional susceptibility maps based on failure probability ( ) and factor of safety (FOS). Using the Maerkang earthquake-induced landslides as a case study, key parameters—including slope, peak ground acceleration, and geological lithology—are analyzed. A comparison is made between FORM and the Mean First Order Second Moment method (MFOSM). The predictive performance of both and FOS is evaluated under different buffer zone sizes and levels of coefficient of variation (COV), using receiver operating characteristic (ROC) curves and balanced accuracy (BA) as evaluation metrics. Results indicate that FORM performs better than MFOSM in addressing the nonlinear behavior of complex slopes, showing an improvement of 5.5% in AUC. Under different buffer sizes, the AUC values for are 82.9%, 84.1%, and 85.0%, all exceeding those of FOS. BA analysis shows that with increasing COV, the optimal thresholds for FORM are 0.08, 0.2, and 0.27, each corresponding to a maximum BA of 0.704. These findings suggest that while COV influences the sensitivity of threshold selection, it does not compromise the model?s predictive performance. The FORM-based method accounts for input uncertainty and provides more stable and detailed landslide risk zoning. It offers a scientifically grounded visualization tool for landslide risk management.

Key words： slope engineering slope stability probabilistic analysis first-order reliability method landslide susceptibility QGIS plugin

引用本文:

佟斌1，崔红志2，姬建1，2. 基于一阶可靠度方法的区域滑坡易发性概率评估与QGIS平台实现[J]. 岩石力学与工程学报, 2025, 44(9): 2456-2469.
TONG Bin1, CUI Hongzhi2, JI Jian1, 2.

Probabilistic assessment of regional landslide susceptibility based on the first-order reliability method and its implementation on the QGIS platform

. , 2025, 44(9): 2456-2469.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0281 或 https://rockmech.whrsm.ac.cn/CN/Y2025/V44/I9/2456

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[38]	YUQIAO Q I N，HUA T A N G，QIN D E N G，et al. Regional seismic slope assessment improvements considering slope aspect and vertical ground motion[J]. Engineering Geology，2019，259：105148.
[39]	GUO Z，TORRA O，HüRLIMANN M，et al. FSLAM：A QGIS plugin for fast regional susceptibility assessment of rainfall-induced landslides[J]. Environmental Modelling and Software，2022，150：105354.
[40]	DREYFUS D，RATHJE E M，JIBSON R W. The influence of different simplified sliding-block models and input parameters on regional predictions of seismic landslides triggered by the Northridge earthquake[J]. Engineering Geology，2013，163：41-54.
[41]	周火明，孔祥辉. 水利水电工程岩石力学参数取值问题与对策[J]. 长江科学院院报，2006，(4)：36-40.(ZHOU Huoming，KONG Xianghui. Problems and countermeasures on parameter selection of rock mechanics in water conservancy and hydropower projects[J]. Journal of Yangtze River Scientific Research Institute，2006，(4)：36-40.(in Chinese))
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