Three‐dimensional slope stability predictions using artificial neural networks

Meng, Jingjing; Mattsson, Hans; Laue, Jan

doi:10.1002/nag.3252

Cited by 28 publications

(16 citation statements)

References 53 publications

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“…The slope safety is generally assessed with a global safety factor (SF) (the ratio of slip resistance forces to the shear forces). To compute a safety factor for a slope, 4 different numerical methods can be employed: the strength reduction method (Zienkiewicz et al 1975; Matsui and San 1992; Dawson et al 1999; Griffiths and Lane 1999; Soren et al 2014), the limit analysis (statically admissible stress field and kinematically admissible deformation, Qiujing et al 2017), the limit equilibrium method (an approximate method assuming the existence of a slip surface of simple shape, Bishop 1955;Jaeger 1971;Fredlund and Krahn 1977; Hoek and Bray 1981; Chen and Chameau 1982; Goodman 1989) and artificial neural networks (machine learning, Meng et al 2021). Nowadays, the coupled analysis approach is receiving more attention in recent years because powerful numerical tools (2D and 3D finite element/difference analyses) are becoming easily available (Vanneschi et al 2018).…”

Section: Safety Factor Computationsmentioning

confidence: 99%

3D large-scale numerical model of open-pit lake slope stability—case study of Lake Most

Renaud

Heib

Burda

2022

Bull Eng Geol Environ

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Almost all post exploitation open pit mines in the world are shaped as a final water reservoir. One of the main hazards is the slope stability of lake banks. To develop a reliability methodology for assessing the long-term stability of flooded open-pit lake, a back analysis was conducted using 2D and 3D large-scale numerical models of Lake Most, which is one of the largest mining lakes in Europe (Czech Republic). The large-scale numerical model was built, based on the site observations, large scale LiDAR data, in situ characterisation tests and statistical analysis of geotechnical data, on DTMs defining the complex geology of the site and on numerous piezometric levels to build the water table . Local and global safety factor (SF) were calculated using the strength reduction method. The results highlighted the reliability of the methodology to combine the geometric model with the geological model to create a large-scale numerical model, to identify local and potentially instable zones and to highlight the role of a weak contact layer. The calculation of 3D SF has shown a very good correlation between the lowest SF and the ground movement observations noted by the Czech authorities.

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Section: Safety Factor Computationsmentioning

confidence: 99%

3D large-scale numerical model of open-pit lake slope stability—case study of Lake Most

Renaud

Heib

Burda

2022

Bull Eng Geol Environ

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“…Previously, ANN was used in various civil engineering problems, such as concrete mixtures' mechanical properties prediction [9,10,11,12], damage detection [13,14,15], structural response estimation [16,17,18], soil behavior modeling [19,20,21]. On the other hand, multiple models using the feed-forward back-propagation neural network technique were developed for slope stability evaluation [22,23,24,25,26]. Das et al [27] proposed a differential evolution neural network model for estimating slope safety factors.…”

Section: Introductionmentioning

confidence: 99%

Comparative Assessment of Various Artificial Neural Network Techniques for Estimating the Safety Factor of Road Embankments

Alqawasmeh¹

2023

GEOMATE

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The slope-stability analysis is one of the most important parameters for ensuring a safe design of road embankments. Currently, various traditional approaches to computing this variable can be seen in the literature. Among them, the finite element method is considered an accurate way to define the safety factor of road embankments. Previous research has investigated the capability of artificial neural networks for rapid safety-factor estimation to overcome the long process of modeling and calculations required in the aforementioned approach. However, most of these studies have focused on a single type of neural network and did not investigate the capabilities of other approaches. Therefore, this study is intended to evaluate the performance of various artificial neural network techniques in predicting the safety factor of road embankments. Within this context, the feed-forward back-propagation, cascade forward neural networks, and general regression neural network results will be compared and benchmarked against various methods used to predict this parameter. Moreover, it is intended to report the influence of neural network architecture on the accuracy of the estimation. Generally, the study results have shown that an artificial neural network provides a rapid and accurate method for calculating road embankments' safety factors. Besides, the best neural network model achieved a coefficient of determination of about 0.91 and a root mean square error of 0.236, which proves the efficiency of this technique. Moreover, the reliability assessment by comparing the neural network models against the traditional methods has shown that they provide better agreement with the finite element technique.

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“…In recent years, the use of data-based techniques such as machine learning (ML) to predict geotechnical issues has received increasing attentions [26,64,68,72]. Of numerous emerging ML techniques, artificial neural networks (ANN) is the most common approach to develop forecasting models of various geotechnical issues such as slope stability [40], soil properties [29,48], bearing capacity [7,28], deep excavation [2,71], mining [12,57], tunnelling [59], jet grouting [58], among others. As strictly developed based on existing data, the quality and size of data play a pivotal role in building ANN models.…”

Section: Introductionmentioning

confidence: 99%

Base resistance of super-large and long piles in soft soil: performance of artificial neural network model and field implications

2022

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This study aims to examine the performance of artificial neural network (ANN) model based on 1137 datasets of super-large (1.0–2.5 m in equivalent diameter) and long (40.2–99 m) piles collected over 37 real projects in the past 10 years in Mekong Delta. Five key input parameters including the load, the displacement, the Standard Penetration Test value of the base soil, the distance between the loading point and pile toe, and the axial stiffness are identified via assessing the results of field load tests. Key innovations of this study are (i) use of large database to evaluate the effect that random selection of training and testing datasets can have on the predicted outcomes of ANN modelling, (ii) a simple approach using multiple learning rates to enhance training process, (iii) clarification of the role that the selected input factors can play in the base resistance, and (iv) new empirical relationships between the pile load and settlement. The results show that the random selection of training and testing datasets can affect significantly the predicted results, for example, the confidence of prediction can drop under 80% when an average R2 > 0.85 is required. The analysis indicates predominant role of the displacement in governing the base resistance of piles, providing significant implication to practical designs.

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Three‐dimensional slope stability predictions using artificial neural networks

Cited by 28 publications

References 53 publications

3D large-scale numerical model of open-pit lake slope stability—case study of Lake Most

3D large-scale numerical model of open-pit lake slope stability—case study of Lake Most

Comparative Assessment of Various Artificial Neural Network Techniques for Estimating the Safety Factor of Road Embankments

Base resistance of super-large and long piles in soft soil: performance of artificial neural network model and field implications

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