Identifying the effects of parameter uncertainty on the reliability of riverbank stability modelling
Identifying the effects of parameter uncertainty on the reliability of riverbank stability modelling
Bank retreat is a key process in fluvial dynamics affecting a wide range of physical, ecological and socioeconomic issues in the fluvial environment. To predict the undesirable effects of bank retreat and to inform effective measures to prevent it, a wide range of bank stability models have been presented in the literature. These models typically express bank stability by defining a factor of safety as the ratio of driving and resisting forces acting on the incipient failure block. These forces are affected by a range of controlling factors that include such aspects as the bank profile (bank height and angle), the geotechnical properties of the bank materials, as well as the hydrological status of the riverbanks. In this paper we evaluate the extent to which uncertainties in the parameterization of these controlling factors feed through to influence the reliability of the resulting bank stability estimate. This is achieved by employing a simple model of riverbank stability with respect to planar failure (which is the most common type of bank stability model) in a series of sensitivity tests and Monte Carlo analyses to identify, for each model parameter, the range of values that induce significant changes in the simulated factor of safety. These identified parameter value ranges are compared to empirically derived parameter uncertainties to determine whether they are likely to confound the reliability of the resulting bank stability calculations. Our results show that parameter uncertainties are typically high enough that the likelihood of generating unreliable predictions is typically very high (> 80% for predictions requiring a precision of < ± 15%). Because parameter uncertainties are derived primarily from the natural variability of the parameters, rather than measurement errors, much more careful attention should be paid to field sampling strategies, such that the parameter uncertainties and consequent prediction unreliabilities can be quantified more robustly.
stability analysis, sensitivity analysis, riverbank, planar failure, factor of safety, monte carlo analysis
219-230
Samadi, A.
cf1ee159-112e-4a4f-8b84-492c50cdaf0e
Amiri-Tokaldany, E.
c9b59da5-81e5-4a5b-8a83-83a3c3bf480d
Darby, S.E.
4c3e1c76-d404-4ff3-86f8-84e42fbb7970
2009
Samadi, A.
cf1ee159-112e-4a4f-8b84-492c50cdaf0e
Amiri-Tokaldany, E.
c9b59da5-81e5-4a5b-8a83-83a3c3bf480d
Darby, S.E.
4c3e1c76-d404-4ff3-86f8-84e42fbb7970
Samadi, A., Amiri-Tokaldany, E. and Darby, S.E.
(2009)
Identifying the effects of parameter uncertainty on the reliability of riverbank stability modelling.
Geomorphology, 106 (3-4), .
(doi:10.1016/j.geomorph.2008.10.019).
Abstract
Bank retreat is a key process in fluvial dynamics affecting a wide range of physical, ecological and socioeconomic issues in the fluvial environment. To predict the undesirable effects of bank retreat and to inform effective measures to prevent it, a wide range of bank stability models have been presented in the literature. These models typically express bank stability by defining a factor of safety as the ratio of driving and resisting forces acting on the incipient failure block. These forces are affected by a range of controlling factors that include such aspects as the bank profile (bank height and angle), the geotechnical properties of the bank materials, as well as the hydrological status of the riverbanks. In this paper we evaluate the extent to which uncertainties in the parameterization of these controlling factors feed through to influence the reliability of the resulting bank stability estimate. This is achieved by employing a simple model of riverbank stability with respect to planar failure (which is the most common type of bank stability model) in a series of sensitivity tests and Monte Carlo analyses to identify, for each model parameter, the range of values that induce significant changes in the simulated factor of safety. These identified parameter value ranges are compared to empirically derived parameter uncertainties to determine whether they are likely to confound the reliability of the resulting bank stability calculations. Our results show that parameter uncertainties are typically high enough that the likelihood of generating unreliable predictions is typically very high (> 80% for predictions requiring a precision of < ± 15%). Because parameter uncertainties are derived primarily from the natural variability of the parameters, rather than measurement errors, much more careful attention should be paid to field sampling strategies, such that the parameter uncertainties and consequent prediction unreliabilities can be quantified more robustly.
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Published date: 2009
Keywords:
stability analysis, sensitivity analysis, riverbank, planar failure, factor of safety, monte carlo analysis
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Local EPrints ID: 65395
URI: http://eprints.soton.ac.uk/id/eprint/65395
ISSN: 0169-555X
PURE UUID: 330ae97d-b812-487d-8e52-3710a6a06c18
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Date deposited: 09 Feb 2009
Last modified: 14 Mar 2024 02:41
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Author:
A. Samadi
Author:
E. Amiri-Tokaldany
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