Minding the geotechnical data gap: appraisal of the variability of key soil parameters for slope stability modelling in Saint Lucia

Shepheard, Casey J.; Vardanega, Paul J.; Holcombe, Elizabeth; Hen-Jones, Rose; Luca, Flavia De

doi:10.1007/s10064-018-01451-5

Cited by 10 publications

(16 citation statements)

References 61 publications

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“…Compilation of geodatabases can help reduce geotechnical uncertainty for design and assessment (cf. Ching and Phoon, 2014;Kulhawy and Mayne, 1990;Roopnarine et al, 2012;Shepheard et al, 2019). A key study Piya (2004) compiled a database of 185 well logs and 328 shallow boreholes to produce a single knowledge base of geological information for the Kathmandu Valley.…”

Section: Geodatabasesmentioning

confidence: 99%

The SAFER geodatabase for the Kathmandu Valley: Geotechnical and geological variability

et al. 2020

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The Kathmandu Valley is within a seismically active region with only few recorded strong-motion data. Geophysical information in the Valley is also sparse. In addition, the absence of an open database which compiles in situ geophysical tests, borehole records, and geotechnical laboratory data is affecting the advancement of knowledge in the region. This article presents SAFER/GEO-591 database, named after the Engineering and Physical Science Research Council (EPSRC)-funded project Seismic Safety and Resilience of Schools in Nepal (SAFER). SAFER/GEO-591 contains data from groundwater wells and boreholes originally commissioned for research and commercial purposes. This work describes (1) the quality assessment and harmonization process conducted on the dataset, (2) the variation of shear-wave velocity ( VS) measurements and geotechnical parameters with depth and elevation in the Valley, (3) the current understanding of the Valley sediment/bedrock topography, and finally (4) new geological cross sections. A companion article presents an updated VS30 map across the Valley based on the contributions of this article. The database can be downloaded from the University of Bristol repository via DOI: https://doi.org/10.5523/bris.3gjcvx51lnpuv269xsa1yrb0rw

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Section: Geodatabasesmentioning

confidence: 99%

The SAFER geodatabase for the Kathmandu Valley: Geotechnical and geological variability

et al. 2020

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“…Physical models may involve different geotechnical factors, which may help these models generate forecasts about slope failures (Tofani et al, 2017;Bicocchi et al, 2019). However, physical models involving different geotechnical factors may be constraint by the underlying mechanics explaining slope failures (Yalcin 2011;Igwe, 2015;Tofani et al, 2017;Bicocchi et al, 2019;Shepheard et al, 2019). Amidst constraints in physical models, data-driven machine-learning (ML) techniques may provide an alternate approach for predicting slope failures (Aloetti and Chowdhury 1999; Kavzoglu et al, 2014;Huang et al, 2017;Park et al, 2019;Asheghi et al, 2020;Moayedi et al, 2021).…”

Section: Saint Lucia Statistical Methodsmentioning

confidence: 99%

“…Statistical methods Porosity, dry density, angle of internal friction, and saturated permeability Shepheard et al (2019)…”

Section: Italymentioning

confidence: 99%

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Determining the Geotechnical Slope Failure Factors via Ensemble and Individual Machine Learning Techniques: A Case Study in Mandi, India

2021

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Landslide disaster risk reduction necessitates the investigation of different geotechnical causal factors for slope failures. Machine learning (ML) techniques have been proposed to study causal factors across many application areas. However, the development of ensemble ML techniques for identifying the geotechnical causal factors for slope failures and their subsequent prediction has lacked in literature. The primary goal of this research is to develop and evaluate novel feature selection methods for identifying causal factors for slope failures and assess the potential of ensemble and individual ML techniques for slope failure prediction. Twenty-one geotechnical causal factors were obtained from 60 sites (both landslide and non-landslide) spread across a landslide-prone area in Mandi, India. Relevant causal factors were evaluated by developing a novel ensemble feature selection method that involved an average of different individual feature selection methods like correlation, information-gain, gain-ratio, OneR, and F-ratio. Furthermore, different ensemble ML techniques (Random Forest (RF), AdaBoost (AB), Bagging, Stacking, and Voting) and individual ML techniques (Bayesian network (BN), decision tree (DT), multilayer perceptron (MLP), and support vector machine (SVM)) were calibrated to 70% of the locations and tested on 30% of the sites. The ensemble feature selection method yielded six major contributing parameters to slope failures: relative compaction, porosity, saturated permeability, slope angle, angle of the internal friction, and in-situ moisture content. Furthermore, the ensemble RF and AB techniques performed the best compared to other ensemble and individual ML techniques on test data. The present study discusses the implications of different causal factors for slope failure prediction.

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“…Recently Shepheard et al (2019) have shown in that Weibull distribution may better describe peak effective friction angle (φ'peak) (number of datapoints (n) = 85) and cohesion intercept (c') (n = 86) for a database of soils from the island of Saint Lucia.…”

Section: Probability Distributions In Geotechnical Engineeringmentioning

confidence: 99%

A database of saturated hydraulic conductivity of fine-grained soils: probability density functions

Feng

Vardanega

2019

Georisk: Assessment and Management of Risk for Engineered Syste

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Saturated hydraulic conductivity is a key soil mechanics parameter which has widespread use in many geotechnical applications. In order to set up stochastic analyses, geotechnical modellers require databases to calibrate the parameter ranges and distributions employed. This paper uses a recently compiled database of saturated hydraulic conductivity measurements called FG/KSAT-1358 and reports on the fitting of various probability density functions to the data of void ratio, liquid limit, water content ratio and negative natural logarithm of ksat. It is shown that the best fit distribution is the lognormal for void ratio, while the loglogistic distribution is most favoured for liquid limit and water content ratio, and the best fit distribution for-ln[ksat(m/s)] is the logistic function. The data of-ln[ksat(m/s)] is then subdivided according to liquid limit level, silt or clay classification, type of hydraulic conductivity test used and sample preparation/condition. When some subdivisions of the database are analysed, the best fit distribution is more variable with GEV and logistic being the most favoured for most of the studied subsets.

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Minding the geotechnical data gap: appraisal of the variability of key soil parameters for slope stability modelling in Saint Lucia

Cited by 10 publications

References 61 publications

The SAFER geodatabase for the Kathmandu Valley: Geotechnical and geological variability

The SAFER geodatabase for the Kathmandu Valley: Geotechnical and geological variability

Determining the Geotechnical Slope Failure Factors via Ensemble and Individual Machine Learning Techniques: A Case Study in Mandi, India

A database of saturated hydraulic conductivity of fine-grained soils: probability density functions

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