Bayesian model averaging assessment on groundwater management under model structure uncertainty

Tsai, Frank T.-C.

doi:10.1007/s00477-010-0382-3

Cited by 40 publications

(24 citation statements)

References 66 publications

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“…There are many literatures about the methods of uncertainty analysis, for example, classical Bayesian techniques (Rojas et al 2010;Singh et al 2010;Tsai 2010), pseudoBayesian (Beven and Binley 1992;Beven and Freer 2001;Hassan et al 2008), geostatistics techniques (Feyen and Caers 2006;Feyen et al 2003;Liang et al 2009), and others. Generally, these methods are mainly focus on inversion of model parameters and uncertainty assessment of model output.…”

Section: Introductionmentioning

confidence: 99%

Sensitivity analysis of the probability distribution of groundwater level series based on information entropy

Wang

2012

Stoch Environ Res Risk Assess

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Information entropy is an effective method to analyze uncertainty in various processes. The principle of maximum entropy (POME) provides a guide line for the parameter estimation of probability density function (PDF). Mutual entropy analysis is well qualified for delineating the nonlinear and complex multivariable relationship. The probability distribution of model output is the element of model uncertainty analysis. In this paper, a synthetic groundwater flow field is build to produce groundwater level series (GLS). The probability distribution of GLS is obtained by the frequency analysis method based on POME and Chi-Squared test. The important uncertainty factors that affect the parameters of PDF of GLS are assessed by the sensitivity analysis methods, which include stepwise regression analysis and mutual entropy analysis. Results of this analysis indicate that most of the GLS follow normal distribution (or log-normal distribution), while a few obey others. The mean and variance of normal GLS are affected differently by the input variables of groundwater model. Mutual entropy analysis is more competitive and appropriate for delineating the nonlinear and nonmonotonic multivariable relationship than stepwise regression analysis.

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Section: Introductionmentioning

confidence: 99%

Sensitivity analysis of the probability distribution of groundwater level series based on information entropy

Wang

2012

Stoch Environ Res Risk Assess

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“…When developing a conceptual model to represent a subsurface formation, uncertainties in model data, structure, and parameters always exist. To accommodate for different sources of uncertainty, strategies as model selection, model elimination, model reduction, model discrimination, and model combination are commonly used to reach a robust model, using single‐model approaches [ Cardiff and Kitanidis , ; Demissie et al ., ; Engdahl et al ., ; Feyen and Caers , ; Kitanidis , ; Gaganis and Smith , ; Irving and Singha , ; Nowak et al ., ; Wingle and Poeter , ] or multimodel approaches [ Doherty and Christensen , ; Li and Tsai , ; Morales‐Casique et al ., ; Neuman , ; Refsgaard et al ., ; Rojas et al ., ; Singh et al ., ; Troldborg et al ., ; Tsai and Li , ; Tsai , ; Ye et al ., ; Wöhling and Vrugt , ].…”

Section: Introductionmentioning

confidence: 99%

“…Wagener and Gupta [] remark that an uncertainty assessment framework should be able to account for the level of contribution of the different sources of uncertainty to the overall uncertainty. In the groundwater area, to advance beyond collection multimodel methods, Li and Tsai [] and Tsai [] present a BMA approach that can separate two sources of uncertainty, which arise from different conceptual models and different parameter estimation methods. These were the first two studies to extend the collection BMA formulation of Hoeting et al .…”

Section: Introductionmentioning

confidence: 99%

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Hierarchical Bayesian model averaging for hydrostratigraphic modeling: Uncertainty segregation and comparative evaluation

Tsai

Elshall

2013

Water Resour. Res.

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[1] Analysts are often faced with competing propositions for each uncertain model component. How can we judge that we select a correct proposition(s) for an uncertain model component out of numerous possible propositions? We introduce the hierarchical Bayesian model averaging (HBMA) method as a multimodel framework for uncertainty analysis. The HBMA allows for segregating, prioritizing, and evaluating different sources of uncertainty and their corresponding competing propositions through a hierarchy of BMA models that forms a BMA tree. We apply the HBMA to conduct uncertainty analysis on the reconstructed hydrostratigraphic architectures of the Baton Rouge aquifer-fault system, Louisiana. Due to uncertainty in model data, structure, and parameters, multiple possible hydrostratigraphic models are produced and calibrated as base models. The study considers four sources of uncertainty. With respect to data uncertainty, the study considers two calibration data sets. With respect to model structure, the study considers three different variogram models, two geological stationarity assumptions and two fault conceptualizations. The base models are produced following a combinatorial design to allow for uncertainty segregation. Thus, these four uncertain model components with their corresponding competing model propositions result in 24 base models. The results show that the systematic dissection of the uncertain model components along with their corresponding competing propositions allows for detecting the robust model propositions and the major sources of uncertainty.

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“…This technique, called model averaging, incorporates the uncertainty associated with model selection into predictions of unknown variables (Hjort and Claeskens, 2003). The model averaging approach has in recent years been applied to several hydrological model applications (Diks and Vrugt, 2010;Tsai, 2010).…”

Section: Multi-model Inferencementioning

confidence: 99%

Statistical summer mass-balance forecast model with application to Brúarjökull glacier, South East Iceland

et al. 2018

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ABSTRACT. Forecasting of glacier mass balance is important for optimal management of hydrological resources, especially where glacial meltwater constitutes a significant portion of stream flow, as is the case for many rivers in Iceland. In this study, a method was developed and applied to forecast the summer mass balance of Brúarjökull glacier in southeast Iceland. In the present study, many variables measured in the basin were evaluated, including glaciological snow accumulation data, various climate indices and meteorological measurements including temperature, humidity and radiation. The most relevant single predictor variables were selected using correlation analysis. The selected variables were used to define a set of potential multivariate linear regression models that were optimized by selecting an ensemble of plausible models showing good fit to calibration data. A mass-balance estimate was calculated as a uniform average across ensemble predictions. The method was evaluated using fivefold cross-validation and the statistical metrics Nash-Sutcliffe efficiency, the ratio of the root mean square error to the std dev. and percent bias. The results showed that the model produces satisfactory predictions when forced with initial condition data available at the beginning of the summer melt season, between 15 June and 1 July, whereas less reliable predictions are produced for longer lead times.

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Bayesian model averaging assessment on groundwater management under model structure uncertainty

Cited by 40 publications

References 66 publications

Sensitivity analysis of the probability distribution of groundwater level series based on information entropy

Sensitivity analysis of the probability distribution of groundwater level series based on information entropy

Hierarchical Bayesian model averaging for hydrostratigraphic modeling: Uncertainty segregation and comparative evaluation

Statistical summer mass-balance forecast model with application to Brúarjökull glacier, South East Iceland

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