prior uncertainty; Popper-Bayes; training image; geological scenario; electrical resistivity tomography; probability perturbation method
Abstract :
[en] In inverse problems, investigating uncertainty in the posterior distribution of model parameters is as important as matching data. In recent years, most efforts have focused on techniques to sample the posterior distribution with reasonable computational costs. Within a Bayesian context, this posterior depends on the prior distribution. However, most of the studies ignore modeling the prior with realistic geological uncertainty. In this paper, we propose a workflow inspired by a Popper-Bayes philosophy, that data should first be used to falsify models, then only be considered for matching. We propose a workflow consisting of three steps: (1) in defining the prior, we interpret multiple alternative geological scenarios from literature (architecture of facies) and site specific data (proportions of facies). Prior spatial uncertainty is modeled using multiple-point geostatistics, where each scenario is defined using a training image. (2) We validate these prior geological scenarios by simulating electrical resistivity tomography (ERT) data on realizations of each scenario and comparing them to field ERT in a lower dimensional space. In this second step, the idea is to probabilistically falsify scenarios with ERT, meaning that scenarios which are incompatible receive an updated probability of zero while compatible scenarios receive a non-zero updated belief. (3) We constrain the hydrogeological model with hydraulic head and ERT using a stochastic search method. The workflow is applied to a synthetic and a field case studies in an alluvial aquifer. This study highlights the importance of considering and estimate prior uncertainty (without data) through a process of probabilistic falsification.
Disciplines :
Geological, petroleum & mining engineering
Author, co-author :
Hermans, Thomas ; Université de Liège > Département ArGEnCo > Géophysique appliquée
Nguyen, Frédéric ; Université de Liège > Département ArGEnCo > Géophysique appliquée
Caers, Jef; Stanford University > Stanford Center for Reservoir Forecasting
Language :
English
Title :
Uncertainty in training image-based inversion of hydraulic head data constrained to ERT data: workflow and case study
Publication date :
2015
Journal title :
Water Resources Research
ISSN :
0043-1397
eISSN :
1944-7973
Publisher :
American Geophysical Union, Washington, United States - District of Columbia
Volume :
51
Pages :
5332-5352
Peer reviewed :
Peer Reviewed verified by ORBi
Funders :
F.R.S.-FNRS - Fonds de la Recherche Scientifique [BE] FRB - Fondation Roi Baudouin [BE]
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