Abstract
Abstract. The use of numerical models for land subsidence prediction above producing hydrocarbon reservoirs has become a common and well-established practice since the early '90s. Usually, uncertainties in the deep rock behavior, which can affect the forecast capability of the models, have been taken into account by running multiple simulations with different constitutive laws and mechanical properties. Then, the most uncertain parameters were calibrated to reproduce available subsidence measurements. The objective of this work is to propose a novel methodological approach for land subsidence prediction and uncertainty quantification by integrating the available monitoring information in numerical models using ad hoc Data Assimilation techniques. The proposed approach allows to: (i) train the model with the available data and improve its accuracy as new information comes in, (ii) quantify the prediction uncertainty by providing confidence intervals and probability measures instead of deterministic outcomes, and (iii) identify the most appropriate rock constitutive model and geomechanical parameters. The methodology is tested in synthetic models of production from hydrocarbon reservoirs. The numerical experiments show that the proposed approach is a promising way to improve the effectiveness and reliability of land subsidence models.
Highlights
The interest and capability of analyzing real world phenomena in a stochastic way have increased in recent years
A way to address this issue relies on the integration of Data Assimilation (DA) techniques into the numerical model, in order to train the model through the available measurements and improve the reliability and accuracy of the solution by reducing the uncertainties
This is done by the generation of many forecast ensembles of Monte Carlo realizations for each constitutive law that could be suitable to describe the behavior of the porous medium, and considering different variability ranges for the main mechanical parameters
Summary
The interest and capability of analyzing real world phenomena in a stochastic way have increased in recent years. L. Gazzola et al.: A novel methodological approach for land subsidence prediction model outcomes and the available measurements, which allows to select the most appropriate ensemble; (ii) a Bayesian approach, i.e. Red Flag (RF) technique, for the identification of the parameter combinations with the highest probability of occurrence, and (iii) an ensemble-based DA technique, i.e. Ensemble Smoother (ES), which updates the model, allowing for a reduction and quantification of the uncertainties. Gazzola et al.: A novel methodological approach for land subsidence prediction model outcomes and the available measurements, which allows to select the most appropriate ensemble; (ii) a Bayesian approach, i.e. Red Flag (RF) technique, for the identification of the parameter combinations with the highest probability of occurrence, and (iii) an ensemble-based DA technique, i.e. Ensemble Smoother (ES), which updates the model, allowing for a reduction and quantification of the uncertainties The aim of this methodology is to study land subsidence in a stochastic way, providing confidence intervals and probability measures instead of deterministic outcomes.
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