Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Sequential probabilistic back analyses of spatially varying soil parameters and slope reliability prediction under rainfall
Abstract Accurately predicting slope reliability under a rainfall/rainstorm event is an important prerequisite for preventing rainfall-induced landslide hazards. However, the predicted probability of slope failure under the rainfall/rainstorm event is often larger than the observed frequency of slope instability. The spatial variability of multiple soil parameters was rarely accounted for. To address this issue, this paper proposes an efficient sequential probabilistic back analyses approach for learning multiple spatially varying soil parameters using Bayesian Updating with Subset simulation (BUS) method. Two survival records of a real slope in India (i.e., the slope stays stable before the rainfall and the slope keeps stable after a 57-day weak rainfall) are successively used in the sequential probabilistic back analyses of soil parameters. The results indicate that the proposed sequential probabilistic back analyses approach can effectively update the distributions of multiple spatially variable soil parameters by the fusion of slope survival records. More accurate statistics of soil parameters can be obtained when additional slope survival records are used in the probabilistic back analyses. Furthermore, two slope failure records under a 3-day heavy rainfall event and a rainfall event ranging from May 1, 2016 to June 30, 2016 in Chibo, India are, respectively, used to predict the slope reliability and further validate the effectiveness of the proposed approach. The predicted probabilities of slope failure under the target rainfall events are well consistent with the actual observation frequency. The proposed approach can provide a powerful and versatile tool for determining the statistics of soil parameters and early warning of landslide hazards under the future rainfall events.
Highlights An efficient back analysis approach is proposed for learning multiple spatially variable soil parameters under rainfall. The BUS method and surrogate models greatly facilitate the sequential probabilistic back analyses of soil parameters. A real unsaturated slope is investigated to illustrate the effectiveness of the proposed approach. The proposed approach can effectively update the distributions of soil parameters and slope reliability prediction. The using of field observations can reduce the uncertainties of soil parameters and enhance the slope reliability prediction.
Sequential probabilistic back analyses of spatially varying soil parameters and slope reliability prediction under rainfall
Abstract Accurately predicting slope reliability under a rainfall/rainstorm event is an important prerequisite for preventing rainfall-induced landslide hazards. However, the predicted probability of slope failure under the rainfall/rainstorm event is often larger than the observed frequency of slope instability. The spatial variability of multiple soil parameters was rarely accounted for. To address this issue, this paper proposes an efficient sequential probabilistic back analyses approach for learning multiple spatially varying soil parameters using Bayesian Updating with Subset simulation (BUS) method. Two survival records of a real slope in India (i.e., the slope stays stable before the rainfall and the slope keeps stable after a 57-day weak rainfall) are successively used in the sequential probabilistic back analyses of soil parameters. The results indicate that the proposed sequential probabilistic back analyses approach can effectively update the distributions of multiple spatially variable soil parameters by the fusion of slope survival records. More accurate statistics of soil parameters can be obtained when additional slope survival records are used in the probabilistic back analyses. Furthermore, two slope failure records under a 3-day heavy rainfall event and a rainfall event ranging from May 1, 2016 to June 30, 2016 in Chibo, India are, respectively, used to predict the slope reliability and further validate the effectiveness of the proposed approach. The predicted probabilities of slope failure under the target rainfall events are well consistent with the actual observation frequency. The proposed approach can provide a powerful and versatile tool for determining the statistics of soil parameters and early warning of landslide hazards under the future rainfall events.
Highlights An efficient back analysis approach is proposed for learning multiple spatially variable soil parameters under rainfall. The BUS method and surrogate models greatly facilitate the sequential probabilistic back analyses of soil parameters. A real unsaturated slope is investigated to illustrate the effectiveness of the proposed approach. The proposed approach can effectively update the distributions of soil parameters and slope reliability prediction. The using of field observations can reduce the uncertainties of soil parameters and enhance the slope reliability prediction.
Sequential probabilistic back analyses of spatially varying soil parameters and slope reliability prediction under rainfall
Pan, Min (Autor:in) / Jiang, Shui-Hua (Autor:in) / Liu, Xin (Autor:in) / Song, Gu-Quan (Autor:in) / Huang, Jinsong (Autor:in)
Engineering Geology ; 328
01.12.2023
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
| Taylor & Francis Verlag | 2022
| Elsevier | 2024