Uncertainty Quantification of Medium‐Term Heat Storage From Short‐Term Geophysical Experiments Using Bayesian Evidential Learning

Hermans, Thomas; Nguyen, Frédéric; Klepikova, Maria; Dassargues, Alain; Caers, Jef

doi:10.1002/2017wr022135

Cited by 68 publications

(90 citation statements)

References 64 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For a high‐dimensional and complex system (e.g., with more than 100 input parameters), a large number of training data are required to train a GP surrogate, which would be extremely time consuming. In this situation, some sampling‐free methods, e.g., Bayesian evidential learning (Hermans et al, 2018) or more advanced dimension reduction techniques (Cunningham and Ghahramani, 2015; Ju et al, 2018), should be used.…”

Section: Discussionmentioning

confidence: 99%

Efficient Bayesian Inverse Modeling of Water Infiltration in Layered Soils

Gao

Zhang

Liu

et al. 2019

Vadose Zone Journal

View full text Add to dashboard Cite

Core Ideas The adaptive GP‐based MCMC was efficient to estimate hydraulic parameters in soils. Accuracy of the estimated parameters was verified by simulating experimental results. These simulations revealed a significant effect of layered structure on soil water flow. Modeling water movement in heterogeneous soils, e.g., layered soils, is an essential but challenging task that requires accurate estimation of multiple sets of soil hydraulic parameters. Markov chain Monte Carlo (MCMC) is a popular but computationally expensive method for parameter estimation. An adaptive Gaussian process (GP)‐based MCMC method proposed in our previous work presents significant computational efficiency. Nevertheless, its performance was evaluated only for synthetic numerical cases and has not been experimentally validated. Furthermore, its applicability in estimating hydraulic parameters of layered soils is still unknown. In this study, we systematically evaluated the performance of the GP‐based MCMC method in estimating the layered soil hydraulic parameters through a water infiltration experiment. It was shown that the proposed method could provide reliable estimations that were very close to those given by the original‐model‐based MCMC but at a much lower computational cost. The simulated soil water dynamics using the estimated parameters revealed a significant effect of layered heterogeneity on water flow. The lower layer(s) with higher water suction may cause persistent unsaturated status of the upper layer(s) during infiltration.

show abstract

Section: Discussionmentioning

confidence: 99%

Efficient Bayesian Inverse Modeling of Water Infiltration in Layered Soils

Gao

Zhang

Liu

et al. 2019

Vadose Zone Journal

View full text Add to dashboard Cite

show abstract

“…McKenna and Blackwell (2004) highlighted the effects of varying permeability and basal heat flow condition on temperature and fluid flow distribution. The role of heterogeneous permeability fields and boundary conditions impacting the fluid flow and temperature pattern are discussed in detail in a recent study by Hermans et al (2018). As pointed out by previous studies, sensitivity analysis is an essential requirement to model complex subsurface systems.…”

Section: Temperature and Fluid Flow Modellingmentioning

confidence: 99%

Hydrogeophysical modelling of Hisarcik (Kütahya) geothermal field, western Turkey

Üner

Ağaçgözgü

Doǧan

2019

Geophysical Prospecting

View full text Add to dashboard Cite

Western Anatolia hosts many low‐to‐moderate and high‐temperature geothermal sources in which active faults play a dominant role to control the recharge and the discharge of geothermal fluid. In this study, we used the two‐dimensional geoelectric structure of Kütahya Hisarcık geothermal field, and created a conceptual hydrogeophysical model that includes faults, real topographical variations and geological units. The temperature distribution and fluid flow pattern are also investigated. The depth extension of Hisarcık Fault, electrical basement and low resistivity anomalies related to the presence of geothermal fluid are determined by using resistivity studies in the area. Numerical simulations suggest that Hisarcık fault functioning as a fluid conduit primarily enables hot fluid to be transported from depth to the surface. It is shown that the locations of predicted outflow vents coincide with those of hot springs in the area.

show abstract

“…We establish the geological uncertainty quantification framework based on BEL, which is briefly reviewed in this section. BEL is not a method, but a prescriptive and normative data-scientific protocol for designing uncertainty quantification within the context of decision making (Athens and Caers, 2019;Hermans et al, 2018;Scheidt et al, 2018). It integrates four constituents in UQ -data, model, prediction, and decision under the scientific methods and philosophy of Bayesianism.…”

Section: Overviewmentioning

confidence: 99%

“…Recently, an uncertainty quantification protocol termed Bayesian evidential learning has been proposed to address decision making under uncertainty, and it has been applied to cases in oil or gas, groundwater contaminant remediation and geothermal energy (Athens and Caers, 2019;Hermans et al, 2018Hermans et al, , 2019Scheidt et al, 2018). It provides explicit standards that need to be reached at each stage of its UQ design with the purpose of decision making, including model falsification, global sensitivity analysis, prior elicitation, and data-science-driven uncertainty reduction under the principle of Bayesianism.…”

Section: Introductionmentioning

confidence: 99%

Automated Monte Carlo-based quantification and updating of geological uncertainty with borehole data (AutoBEL v1.0)

2020

Self Cite

View full text Add to dashboard Cite

Abstract. Geological uncertainty quantification is critical to subsurface modeling and prediction, such as groundwater, oil or gas, and geothermal resources, and needs to be continuously updated with new data. We provide an automated method for uncertainty quantification and the updating of geological models using borehole data for subsurface developments within a Bayesian framework. Our methodologies are developed with the Bayesian evidential learning protocol for uncertainty quantification. Under such a framework, newly acquired borehole data directly and jointly update geological models (structure, lithology, petrophysics, and fluids), globally and spatially, without time-consuming model rebuilding. To address the above matters, an ensemble of prior geological models is first constructed by Monte Carlo simulation from prior distribution. Once the prior model is tested by means of a falsification process, a sequential direct forecasting is designed to perform the joint uncertainty quantification. The direct forecasting is a statistical learning method that learns from a series of bijective operations to establish “Bayes–linear-Gauss” statistical relationships between model and data variables. Such statistical relationships, once conditioned to actual borehole measurements, allow for fast-computation posterior geological models. The proposed framework is completely automated in an open-source project. We demonstrate its application by applying it to a generic gas reservoir dataset. The posterior results show significant uncertainty reduction in both spatial geological model and gas volume prediction and cannot be falsified by new borehole observations. Furthermore, our automated framework completes the entire uncertainty quantification process efficiently for such large models.

show abstract

Uncertainty Quantification of Medium‐Term Heat Storage From Short‐Term Geophysical Experiments Using Bayesian Evidential Learning

Cited by 68 publications

References 64 publications

Efficient Bayesian Inverse Modeling of Water Infiltration in Layered Soils

Efficient Bayesian Inverse Modeling of Water Infiltration in Layered Soils

Hydrogeophysical modelling of Hisarcik (Kütahya) geothermal field, western Turkey

Automated Monte Carlo-based quantification and updating of geological uncertainty with borehole data (AutoBEL v1.0)

Contact Info

Product

Resources

About