Your search keyword '"History matching"' showing total 2,459 results

1. Uncertainty Quantification in Rate Transient Analysis of Multi-Fractured Tight Gas Wells Exhibiting Gas–Water Two-Phase Flow.

Author

Wu, Yonghui, Zheng, Rongchen, Ma, Liqiang, and Feng, Xiujuan

Subjects

TWO-phase flow, GAS wells, TRANSIENT analysis, GAS reservoirs, GAS flow, HORIZONTAL wells

Abstract

The production performances of fractured tight gas wells are closely related to several complex and unknown factors, including the formation properties, fracture parameters, gas–water two-phase flow, and other nonlinear flow mechanisms. The rate transient analysis (RTA) results have significant uncertainties, which should be quantified to evaluate the formation and fracturing treatment better. This paper provides an efficient method for uncertainty quantification in the RTA of fractured tight gas wells with multiple unknown factors incorporated. The theoretical model for making forward predictions is based on a trilinear flow model, which incorporates the effects of two-phase flow and other nonlinear flow mechanisms. The normalized rates and material balance times of both water and gas phases are regarded as observations and matched with the theoretical model. The unknowns in the model are calibrated using the ensemble Kalman filter (EnKF), which applies an ensemble of multiple realizations to match the observations and updates the unknown parameters step by step. Finally, a comprehensive field case from Northwestern China is implemented to benchmark the proposed method. The results show that the parameters and rate transient responses have wide ranges and significant uncertainties before history matching, while all the realizations in the ensemble can have good matches to the field data after calibration. The posterior distribution of each unknown parameter in the model can be obtained after history matching, which can be used to quantify the uncertainties in the RTA of the fractured tight gas wells. The ranges and uncertainties of the parameters are significantly narrowed down, but the parameters are still with significant uncertainties. The main contribution of the paper is the provision of an efficient integrated workflow to quantify the uncertainties in RTA. It can be readily used in field applications of multi-fractured horizontal wells from tight gas reservoirs. [ABSTRACT FROM AUTHOR]

Published

2024

2. An iterative workflow introduced to model complex heterogeneous reservoirs: an example from NEAG-2 Field, north Western Desert, Egypt.

Author

Rashad, Ola, El-Barkooky, Ahmed Niazy, El-Araby, Abd El-Moneim, El-Tonbary, Mohamed, and Zahran, Mohamed

Subjects

SAND bars, TIDAL flats, FLUID flow, GAUSSIAN function, FACIES

Abstract

The challenge in modeling complex-heterogeneous reservoirs is to accurately represent dimensions, trends, and quality for each facies type and to avoid overestimating or underestimating the reservoir elements. NEAG-2 Field has a highly heterogeneous reservoir system of the Albian-Cenomanian age; it is the main reservoir system in the East Abu Gharadig Basin, and it is the main oil contributor in the north Western Desert of Egypt. Therefore, developing a water-tight model for such a complex system can act as an analog for any similar complex-heterogenous system worldwide. In the NEAG-2 Field, a representative reservoir model and dynamic simulation for its reservoir are required to restore the field's production. The field has an excellent yet unique performance, and it recorded an average production rate of 9000 bbl/d from five producer wells in 2018. Since that peak, production has been declining, with a current total of 1390 bbl/d from four wells. This production behavior was not modeled nor predicted in the previous modeling trials. Therefore, we introduce a mature model to improve production forecasts and optimize recovery while giving an example of how the complex heterogeneous reservoirs should be properly modeled. An object-based geostatistical algorithm was applied in modeling the reservoir facies, and a truncated Gaussian algorithm was applied for the background (non-reservoir) facies. The property models were distributed using Gaussian simulation algorithms, with the guidance of variogram analysis. Three reservoir facies were distinguished, with specific geometry, orientation, and porosity–permeability characteristics to model their flow behavior. The highest-quality facies (type 1) were tidal channels, followed by moderate-quality (type 2) tidal sand bars, which had smaller lateral dimensions compared to the channels. The lowest quality sand facies (type 3) were embodied as mixed tidal flats. Each facies body, reservoir zone, and field segment was modeled distinctly to ensure a representative statistical range for each. The integrated workflow developed a flow-unit-based model that preserved the reservoir heterogeneity and fluid flow complexity, which improved the forecasting for reviving the field production. The final results of this static model were validated by the production data and the history matching of each well. [ABSTRACT FROM AUTHOR]

Published

2024

3. Calibration under Uncertainty Using Bayesian Emulation and History Matching: Methods and Illustration on a Building Energy Model.

Author

Domingo, Dario, Royapoor, Mohammad, Du, Hailiang, Boranian, Aaron, Walker, Sara, and Goldstein, Michael

Subjects

*CALIBRATION, *FORECASTING, *GASES, *TEMPERATURE, *PERCENTILES

Abstract

Energy models require accurate calibration to deliver reliable predictions. This study offers statistical guidance for a systematic treatment of uncertainty before and during model calibration. Statistical emulation and history matching are introduced. An energy model of a domestic property and a full year of observed data are used as a case study. Emulators, Bayesian surrogates of the energy model, are employed to provide statistical approximations of the energy model outputs and explore the input parameter space efficiently. The emulator's predictions, alongside quantified uncertainties, are then used to rule out parameter configurations that cannot lead to a match with the observed data. The process is automated within an iterative procedure known as history matching (HM), in which simulated gas consumption and temperature data are simultaneously matched with observed values. The results show that only a small percentage of parameter configurations (0.3% when only gas consumption is matched, and 0.01% when both gas and temperature are matched) yielded outputs matching the observed data. This demonstrates HM's effectiveness in pinpointing the precise region where model outputs align with observations. The proposed method is intended to offer analysts a robust solution to rapidly explore a model's response across the entire input space, rule out regions where a match with observed data cannot be achieved, and account for uncertainty, enhancing the confidence in energy models and their viability as a decision support tool. [ABSTRACT FROM AUTHOR]

Published

2024

4. 深部煤层气井合理排采制度优化设计研究 ——以鄂尔多斯盆地东缘神府区块为例.

Author

王小东, 石军太, 郝鹏灵, 王宇川, 曹敬添, 王 涛, 范倩雯, and 张亚飞

Subjects

WATER temperature, STRESS fractures (Orthopedics), DRAINAGE, COALBED methane, COAL, PULVERIZED coal, COMPRESSIBILITY, GAS wells

Abstract

Copyright of Geology & Exploration is the property of Geology & Exploration Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

5. History Matching Reservoir Models With Many Objective Bayesian Optimization

Author

Steven Samoil, Clyde Fare, Kirk E. Jordan, and Zhangxin Chen

Subjects

Bayesian optimization, history matching, reservoir simulation, Electronic computers. Computer science, QA75.5-76.95

Abstract

ABSTRACT Reservoir models for predicting subsurface fluid and rock behaviors can now include upwards of billions (and potentially trillions) of grid cells and are pushing the limits of computational resources. History matching, where models are updated to match existing historical data more closely, is conducted to reduce the number of simulation runs and is one of the primary time‐consuming tasks. As models get larger the number of parameters to match increases, and the number of objective functions increases, and traditional methods start to reach their limitations. To solve this, we propose the use of Bayesian optimization (BO) in a hybrid cloud framework. BO iteratively searches for an optimal solution in the simulations campaign through the refinement of a set of priors initialized with a set of simulation results. The current simulation platform implements grid management and a suite of linear solvers to perform the simulation on large scale distributed‐memory systems. Our early results using the hybrid cloud implementation shown here are encouraging on tasks requiring over 100 objective functions, and we propose integrating BO as a built‐in module to efficiently iterate to find an optimal history match of production data in a single package platform. This paper reports on the development of the hybrid cloud BO based history matching framework and the initial results of the application to reservoir history matching.

Published

2024

6. Study of Spatial Feature Extraction Methods for Surrogate Models of Numerical Reservoir Simulation

Author

Zhang, Jin-ding, Zhang, Kai, Zhang, Li-ming, Liu, Pi-yang, Fu, Wen-hao, Zhang, Wei-long, Kang, Jin-zheng, Wu, Wei, Series Editor, and Lin, Jia'en, editor

Published

2024

7. Constraint optimization of an integrated production model utilizing history matching and production forecast uncertainty through the ensemble Kalman filter

Author

Mehdi Fadaei, Mohammad Javad Ameri, and Yousef Rafiei

Subjects

History matching, Uncertainty, Constraint optimization, Integrated model, Ensemble Kalman filter, Medicine, Science

Abstract

Abstract The calibration of reservoir models using production data can enhance the reliability of predictions. However, history matching often leads to only a few matched models, and the original geological interpretation is not always preserved. Therefore, there is a need for stochastic methodologies for history matching. The Ensemble Kalman Filter (EnKF) is a well-known Monte Carlo method that updates reservoir models in real time. When new production data becomes available, the ensemble of models is updated accordingly. The initial ensemble is created using the prior model, and the posterior probability function is sampled through a series of updates. In this study, EnKF was employed to evaluate the uncertainty of production forecasts for a specific development plan and to match historical data to a real field reservoir model. This study represents the first attempt to combine EnKF with an integrated model that includes a genuine oil reservoir, actual production wells, a surface choke, a surface pipeline, a separator, and a PID pressure controller. The research optimized a real integrated production system, considering the constraint that there should be no slug flow at the inlet of the separator. The objective function was to maximize the net present value (NPV). Geological data was used to model uncertainty using Sequential Gaussian Simulation. Porosity scenarios were generated, and conditioning the porosity to well data yielded improved results. Ensembles were employed to balance accuracy and efficiency, demonstrating a reduction in porosity uncertainty due to production data. This study revealed that utilizing a PID pressure controller for the production separator can enhance oil production by 59% over 20 years, resulting in the generation of 2.97 million barrels of surplus oil in the field and significant economic gains.

Published

2024

8. Bayesian History Matching Applied to the Calibration of a Gravity Wave Parameterization.

Author

King, Robert C., Mansfield, Laura A., and Sheshadri, Aditi

Subjects

*GRAVITY waves, *CLIMATE change models, *PARAMETERIZATION, *QUASI-biennial oscillation (Meteorology), *ATMOSPHERIC waves, *ZONAL winds

Abstract

Breaking atmospheric gravity waves (GWs) in the tropical stratosphere are essential in driving the roughly 2‐year oscillation of zonal winds in this region known as the Quasi‐Biennial Oscillation (QBO). As Global Climate Models (GCM)s are not typically able to directly resolve the spectrum of waves required to drive the QBO, parameterizations are necessary. Such parameterizations often require knowledge of poorly constrained physical parameters. In the case of the spectral gravity parameterization used in this work, these parameters are the total equatorial GW stress and the half width of phase speed distribution. Radiosonde observations are used to obtain the period and amplitude of the QBO, which are compared against values obtained from a GCM. We utilize two established calibration techniques to obtain estimates of the range of plausible parameter values: History matching & Ensemble Kalman Inversion (EKI). History matching is found to reduce the size of the initial range of plausible parameters by a factor of 98%, requiring only 60 model integrations. EKI cannot natively provide any uncertainty quantification but is able to produce a single best estimate of the calibrated values in 25 integrations. When directly comparing the approaches using the Calibrate, Emulate, Sample method to produce a posterior estimate from EKI, history matching produces more compact posteriors with fewer model integrations at lower ensemble sizes compared to EKI; however, these differences become less apparent at higher ensemble sizes. Plain Language Summary: Atmospheric gravity waves (GWs) are buoyancy driven oscillations which propagate through the atmosphere and deposit momentum where they break. This momentum exchange plays a significant role in setting various large‐scale atmospheric phenomena, of which a prominent example is the Quasi‐Biennial Oscillation (QBO), a roughly 2‐year oscillation of winds in the tropical stratosphere. Many of the waves responsible for creating these large scale patterns are too small to be simulated by climate models. Thus, we use parameterizations to estimate their impact on the large scale. These parameterizations have settings that require tuning, to enable the model to produce variability that matches the observed climate. In this work, we utilize and compare two techniques: History matching and Ensemble Kalman Inversion. These methods are combined with observations of the QBO to tune the settings for the GW parameterization. Key Points: History matching and Ensemble Kalman Inversion (EKI) were used to calibrate two parameters in a gravity wave parameterization to Quasi‐Biennial Oscillation observationsHistory matching was found to rapidly and compactly produce an estimate of the plausible space of parameters when compared to EKIEKI was found to be strong at single best estimates of the calibrated parameters at low ensemble sizes requiring few iterations [ABSTRACT FROM AUTHOR]

Published

2024

9. Constraint optimization of an integrated production model utilizing history matching and production forecast uncertainty through the ensemble Kalman filter

Author

Fadaei, Mehdi, Ameri, Mohammad Javad, and Rafiei, Yousef

Published

2024

10. Direct Comparison of Numerical Simulations and Experiments of CO2 Injection and Migration in Geologic Media: Value of Local Data and Forecasting Capability.

Author

Saló-Salgado, Lluís, Haugen, Malin, Eikehaug, Kristoffer, Fernø, Martin, Nordbotten, Jan M., and Juanes, Ruben

Subjects

CARBON sequestration, COMPUTER simulation, POROUS materials, CARBON dioxide, MULTIPHASE flow, LOCAL mass media

Abstract

The accuracy and robustness of numerical models of geologic CO 2 sequestration are almost never quantified with respect to direct observations that provide a ground truth. Here, we conduct CO 2 injection experiments in meter-scale, quasi-2D tanks with porous media representing stratigraphic sections of the subsurface, and compare them to numerical simulations of those experiments. We evaluate (1) the value of prior knowledge of the system, expressed in terms of ex situ measurements of the tank sands' multiphase flow properties (local data), with respect to simulation accuracy; and (2) the forecasting capability of history-matched numerical models, when applied to different settings. We match three versions of a numerical simulation model—each with access to an increasing level of local data—to a CO 2 injection experiment in Tank 1 ( 89.7 × 47 × 1.05 cm). Matching is based on a quantitative comparison of CO 2 migration at different times from timelapse image analysis. Next, use the matched models to make a forecast of a different injection scenario in Tank 1 and, finally, a different injection scenario in Tank 2 ( 2.86 × 1.3 × 0.019 m), which represents an altogether different stratigraphic section. The simulation model can qualitatively match the observed free-phase and dissolved CO 2 plume migration and convective mixing. Quantitatively, simulations are accurate during the injection phase, but their concordance decreases with time. Using local data reduces the time required to history match, although the forecasting capability of matched models is similar. The sand–water– CO 2 (g) system is very sensitive to effective permeability and capillary pressure changes; where heterogeneous structures are present, accurate deterministic estimates of CO 2 migration are difficult to obtain. [ABSTRACT FROM AUTHOR]

Published

2024

11. A History Matching Study for the FluidFlower Benchmark Project.

Author

Tian, Xiaoming, Wapperom, Michiel, Gunning, James, Jackson, Samuel, Wilkins, Andy, Green, Chris, Ennis-King, Jonathan, and Voskov, Denis

Subjects

GEOPHYSICS, MAXIMUM likelihood statistics, SPATIAL variation, CARBON dioxide

Abstract

In this study, we conduct a comprehensive history matching study for the FluidFlower benchmark model. This benchmark was prepared and organized by the University of Bergen, the University of Stuttgart, and Massachusetts Institute of Technology, for promoting understanding of the complex physics of geological carbon storage (GCS) through in-house experiments and numerical simulations. This paper synthesizes the experiences of history matching the benchmark data encountered by the Delft-DARTS and CSIRO participants. History matching is first performed based on a low-dimensional-zonated structured model using a simple Poisson-like solver. The permeability of six facies and two faults is inferred in this stage to match the digitized concentration data. The history matching is then further enhanced to richer spatial and physical models to capture the spatial variation of permeability and buoyancy effects, using an unstructured grid. Efficient adjoint methods are used to evaluate the gradient used in the optimization of data misfits or equivalent Bayesian log-likelihoods. With efficient optimization methods available for both maximum a posteriori model inference and Randomized Maximum Likelihood methods for model uncertainty, we perform history matching using both binary and continuous concentration observations. The results show that the tracer plumes in the enriched model match the experimental plumes more accurately compared with the results from the parsimonious-zonated model. The history matching results based on the concentration observations provide more similar plume shapes compared with the case based on the binary observations. The permeability difference between the model before and after history matching reveals that the tracer plume zone and the high permeable zone are the regions of high sensitivity in terms of data misfit between the model response and observations. Surprisingly, CO 2 concentration plume forecasts based on these history-matched models were not especially sensitive to the improvements observed in the enhanced model. [ABSTRACT FROM AUTHOR]

Published

2024

12. A New Method for Numerical Simulation of Coalbed Methane Pilot Horizontal Wells—Taking the Bowen Basin C Pilot Area in Australia as an Example.

Author

Wang, Xidong, Duan, Lijiang, Zhang, Songhang, Tang, Shuheng, Lv, Jianwei, and Li, Xudong

Subjects

COALBED methane, HORIZONTAL wells, COMPUTER simulation, GAS wells, DISTRIBUTION (Probability theory), TECHNOLOGICAL innovations, SHALE gas, NATURAL gas

Abstract

Coalbed methane (CBM) pilot wells typically exhibit a short production period, necessitating evaluation of their estimated ultimate recovery (EUR) through numerical simulation. Utilizing limited geological data from the pilot areas to finish history matching and subsequent production forecasting presents substantial challenges. This paper introduces a comprehensive numerical simulation workflow for CBM pilot wells, encompassing the following steps. Initially, geological parameters are categorized into two groups based on their statistical distribution trends: trend parameters (i.e., gas content, permeability, Langmuir volume, and Langmuir pressure) and non-trend parameters (i.e., fracture porosity, gas–water relative permeability, and rock compressibility). The probability method is employed to ascertain the probable high and low limits for trend parameter distributions, while empirical or analogous methods are applied to define the boundaries for non-trend parameters. Subsequently, the parameter sensitivity analysis is conducted to understand the influence of varying parameters on cumulative gas and water production. Conclusively, experimental design algorithms generate over 100 simulation cases using the identified sensitive parameters, from which the top ten optimal cases are chosen for EUR prediction. This workflow features two technological innovations: (1) considering the most comprehensive set of reservoir parameters for uncertainty and sensitivity analyses, and (2) considering the matching accuracy of both cumulative production and dynamic production trends when selecting optimal matching cases. This approach was successfully implemented in the C pilot area of the Bowen Basin, Australia. In addition, it offers valuable insights for numerical simulation of unconventional natural gases, such as shale gas. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Local Parameterization-Based Probabilistic Cooperative Coevolutionary Algorithm for History Matching.

Author

Zhang, Jinding, Guo, Xin, Zhao, Zihao, Zhang, Kai, Ma, Xiaopeng, Liu, Weifeng, Wang, Jian, Liu, Chen, Yang, Yongfei, Yao, Chuanjin, and Yao, Jun

Subjects

OPTIMIZATION algorithms, PARAMETERIZATION, COEVOLUTION, ALGORITHMS, COMPUTER simulation

Abstract

History matching, as an essential part of reservoir development, aims to infer high-dimensional geological parameters of a reservoir with a small amount of observation. Despite the rapid development of optimization algorithms, finding optimal solutions for history matching is still challenging because of the large number of parameters that depend on the grid blocks of the numerical simulation model. Motivated by the divide-and-conquer strategy, in this work a novel probabilistic cooperative coevolutionary framework based on local parameterization (LP-PCC) is constructed to improve the convergence of the history matching of large-scale problems. First, the high-dimensional model parameters are decomposed based on smooth local parameterization, in which the divided low-dimensional parameters can reconstruct smooth boundaries of the geological structure during optimization. After that, a contribution-based cooperative coevolutionary algorithm is adopted to optimize the low-dimensional parameters in a round-robin fashion and allocate the computational resources reasonably. To further improve the performance of cooperative coevolution, a new probabilistic method integrated with contribution information is presented to select the subcomponents to be optimized. This framework incorporates domain knowledge for decomposition and a probabilistic mechanism to select subcomponents with large probability, which enhances both convergence and exploration in cooperative coevolution. Two synthetic reservoir cases are designed to validate the effectiveness and efficiency of the proposed method. The numerical results indicate that, compared with traditional strategies, the method can obtain better history-matching results and be adapted to large-scale reservoir problems. [ABSTRACT FROM AUTHOR]

Published

2024

14. Production Well Placement and History Matching by Hyperparametric Optimization and Machine Learning.

Author

Donskoi, A., Medvedev, A., Shchudro, T., Terekhov, K., and Vassilevski, Yu.

Abstract

This article explores methods for resolving two practical issues in reservoir engineering: discovering an optimal position for the production well on a grid, and recovering unknown fracture position based on the historical production data. To speed up the conventional approach (numerical simulation and the full grid search), we assess application of optimization techniques from the Hyperopt package as well as several machine learning models. [ABSTRACT FROM AUTHOR]

Published

2024

15. Bayesian History Matching Applied to the Calibration of a Gravity Wave Parameterization

Author

Robert C. King, Laura A. Mansfield, and Aditi Sheshadri

Subjects

Quasi‐Biennial Oscillation, history matching, ensemble Kalman inversion, gravity waves, calibration, parameterizations, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Breaking atmospheric gravity waves (GWs) in the tropical stratosphere are essential in driving the roughly 2‐year oscillation of zonal winds in this region known as the Quasi‐Biennial Oscillation (QBO). As Global Climate Models (GCM)s are not typically able to directly resolve the spectrum of waves required to drive the QBO, parameterizations are necessary. Such parameterizations often require knowledge of poorly constrained physical parameters. In the case of the spectral gravity parameterization used in this work, these parameters are the total equatorial GW stress and the half width of phase speed distribution. Radiosonde observations are used to obtain the period and amplitude of the QBO, which are compared against values obtained from a GCM. We utilize two established calibration techniques to obtain estimates of the range of plausible parameter values: History matching & Ensemble Kalman Inversion (EKI). History matching is found to reduce the size of the initial range of plausible parameters by a factor of 98%, requiring only 60 model integrations. EKI cannot natively provide any uncertainty quantification but is able to produce a single best estimate of the calibrated values in 25 integrations. When directly comparing the approaches using the Calibrate, Emulate, Sample method to produce a posterior estimate from EKI, history matching produces more compact posteriors with fewer model integrations at lower ensemble sizes compared to EKI; however, these differences become less apparent at higher ensemble sizes.

Published

2024

16. An improved coupled flow-geomechanical model for cyclic steam stimulation

Author

YADALI JAMALOEI Benyamin

Subjects

heavy oil production, cyclic steam stimulation, flow-geomechanical model, spongy-rock approach, dilation-recompaction, history matching, Petroleum refining. Petroleum products, TP690-692.5

Abstract

Considering the pore deformation and permeability changes during dilation-recompaction in cyclic steam stimulation (CSS), an existing geomechanical model is improved and thermo-mechanically coupled with the flow equations to form a coupled flow-geomechanical model. The impacts of dilation-recompaction parameters can be quantified through sensitivity analysis and uncertainty assessment utilizing the synergy between Latin hypercube designs and response surface methodology. The improved coupled flow-geomechanical model allows a more reasonable history-matching of steam injection pressure and volume and oil/water production volume. In both the linear and quadratic models, the rise in recompaction pressure has the most significant effect on the rise in the volumes of steam injection and water production, both rock compressibility and recompaction pressure are positively correlated with steam injectivity and oil/water production, and the dilation pressure is negatively correlated with steam injectivity and oil/water production. In the linear model, dilation pressure has the most significant negative impact on the cumulative oil production, and compressibility and recompaction pressure are positively correlated with oil production. In the quadratic model, the rise in recompaction pressure has the most significant effect on the rise in the cumulative volumes of oil/water production and steam injection. The interactions between the dilation/recompaction pressures and spongy-rock compressibility negatively affect the cumulative volumes of oil/water production and steam injection.

Published

2023

17. Calibration under Uncertainty Using Bayesian Emulation and History Matching: Methods and Illustration on a Building Energy Model

Author

Dario Domingo, Mohammad Royapoor, Hailiang Du, Aaron Boranian, Sara Walker, and Michael Goldstein

Subjects

building energy models, uncertainty, model discrepancy, history matching, simultaneous match of diverse data, Technology

Abstract

Energy models require accurate calibration to deliver reliable predictions. This study offers statistical guidance for a systematic treatment of uncertainty before and during model calibration. Statistical emulation and history matching are introduced. An energy model of a domestic property and a full year of observed data are used as a case study. Emulators, Bayesian surrogates of the energy model, are employed to provide statistical approximations of the energy model outputs and explore the input parameter space efficiently. The emulator’s predictions, alongside quantified uncertainties, are then used to rule out parameter configurations that cannot lead to a match with the observed data. The process is automated within an iterative procedure known as history matching (HM), in which simulated gas consumption and temperature data are simultaneously matched with observed values. The results show that only a small percentage of parameter configurations (0.3% when only gas consumption is matched, and 0.01% when both gas and temperature are matched) yielded outputs matching the observed data. This demonstrates HM’s effectiveness in pinpointing the precise region where model outputs align with observations. The proposed method is intended to offer analysts a robust solution to rapidly explore a model’s response across the entire input space, rule out regions where a match with observed data cannot be achieved, and account for uncertainty, enhancing the confidence in energy models and their viability as a decision support tool.

Published

2024

18. Comparative Study of Variance-Based and One-Parameter-At-A-Time Sensitivity Analysis Method for Polymer Flood Performance History Matching

Author

Sitravellu, Bohgaindran Raj, Yagoub, Sami Abdelrahman Musa, Aulia, Akmal, Hasiholan, Bonavian, Mukhtar, Yasir M. F., Wu, Wei, Series Editor, and Lin, Jia’en, editor

Published

2023

19. Reducing the Geological Uncertainty by History Matching

Author

Yousefzadeh, Reza, Kazemi, Alireza, Ahmadi, Mohammad, Gholinezhad, Jebraeel, Gholinezhad, Jebraeel, Series Editor, Bentley, Mark, Editorial Board Member, Akanji, Lateef, Editorial Board Member, Sabil, Khalik Mohamad, Editorial Board Member, Agar, Susan, Editorial Board Member, Soga, Kenichi, Editorial Board Member, Sulaimon, A. A., Editorial Board Member, Yousefzadeh, Reza, Kazemi, Alireza, and Ahmadi, Mohammad

Published

2023

20. Uncertainty Management in Reservoir Engineering

Author

Yousefzadeh, Reza, Kazemi, Alireza, Ahmadi, Mohammad, Gholinezhad, Jebraeel, Gholinezhad, Jebraeel, Series Editor, Bentley, Mark, Editorial Board Member, Akanji, Lateef, Editorial Board Member, Sabil, Khalik Mohamad, Editorial Board Member, Agar, Susan, Editorial Board Member, Soga, Kenichi, Editorial Board Member, Sulaimon, A. A., Editorial Board Member, Yousefzadeh, Reza, Kazemi, Alireza, and Ahmadi, Mohammad

Published

2023

21. Four-Dimensional History Matching Using ES-MDA and Flow-Based Distance-to-Front Measurement.

Author

Barrela, Eduardo, Berthet, Philippe, Trani, Mario, Thual, Olivier, and Lapeyre, Corentin

Subjects

*DATA reduction, *ELECTRONIC data processing, *TEST methods

Abstract

The use of 4D seismic data in history matching has been a topic of great interest in the hydrocarbon industry as it can provide important information regarding changes in subsurfaces caused by fluid substitution and other factors where well data is not available. However, the high dimensionality and uncertainty associated with seismic data make its integration into the history-matching process a challenging task. Methods for adequate data reduction have been proposed in the past, but most address 4D information mismatch from a purely mathematical or image distance-based standpoint. In this study, we propose a quantitative and flow-based approach for integrating 4D seismic data into the history-matching process. By introducing a novel distance parametrization technique for measuring front mismatch information using streamlines, we address the problem from a flow-based standpoint; at the same time, we maintain the amount of necessary front data at a reduced and manageable amount. The proposed method is tested, and its results are compared on a synthetic case against another traditional method based on the Hausdorff distance. The effectiveness of the method is also demonstrated on a semi-synthetic model based on a real-case scenario, where the standard Hausdorff methodology could not be applied due to high data dimensionality. [ABSTRACT FROM AUTHOR]

Published

2023

22. Marginalized iterative ensemble smoothers for data assimilation.

Author

Stordal, Andreas S., Lorentzen, Rolf J., and Fossum, Kristian

Subjects

*COST functions, *KALMAN filtering, *MEASUREMENT errors

Abstract

Data assimilation is an important tool in many geophysical applications. One of many key elements of data assimilation algorithms is the measurement error that determines the weighting of the data in the cost function to be minimized. Although the algorithms used for data assimilation treat the measurement uncertainty as known, it is in many cases estimated or set based on some expert opinion. Here we treat the measurement uncertainty as a hyperparameter in a fully Bayesian hierarchical model and derive a new class of iterative ensemble methods for data assimilation where the measurement uncertainty is integrated out. The proposed algorithms are compared with the standard iterative ensemble smoother on a 2D synthetic reservoir model. [ABSTRACT FROM AUTHOR]

Published

2023

23. 基于微地震约束的多尺度复杂压裂缝网自动反演新方法.

Author

李俊超, 戴 城, and 方思冬

Abstract

Copyright of Natural Gas Industry is the property of Natural Gas Industry Journal Agency and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

24. Calibrating the Reservoir Model of the Garraf Oil Field.

Author

Abdulredha, Sarah Kamil and Al-jwad, Mohammed Saleh

Abstract

Copyright of Iraqi Journal of Chemical & Petroleum Engineering is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

25. A New Approach for Production Prediction in Onshore and Offshore Tight Oil Reservoir.

Author

Qiu, Kaixuan, Fan, Kaifeng, Chen, Xiaolin, Lei, Gang, Wei, Shiming, Navik, Rahul, and Li, Jia

Subjects

PETROLEUM reservoirs, ORDINARY differential equations, PARTIAL differential equations, ANALYTICAL solutions, INTEGRAL transforms

Abstract

Rapid technological advances have accelerated offshore and onshore tight oil extraction to meet growing energy demand. Reliable tools to carry out production prediction are essential for development of unconventional reservoirs. The existed tri-linear analytical solutions are verified to be versatile enough to capture fundamental flow mechanisms and make accurate production predictions. However, these solutions are obtained in Laplace space with the Laplace transform and numerical inversion, which may lead to uncertainty in the solution. In this paper, a general analytical solution is derived in real-time space through integral transform and average pressure substitution. Namely, the partial differential equations describing subsurface fluid flow are firstly triple-integrated and then the obtained volume average pressure are replaced with the rate-dependent expressions. Furthermore, the ordinary differential equations related to oil rate are solved analytically in real-time space. To validate our model, this derived solution is verified against two numerical models constructed with two typical physical configurations. The great match indicates the accuracy and applicability of the analytical solution. According to the developed workflow, two field cases including offshore and onshore tight oilfield data are selected for history matching and production prediction. This new approach not only makes the obtained solution more simplified, but also helps field engineers diagnose flow patterns more quickly to better optimize production schemes. [ABSTRACT FROM AUTHOR]

Published

2023

26. An improved coupled flow-geomechanical model for cyclic steam stimulation.

Author

Benyamin, YADALI JAMALOEI

Published

2023

27. Reservoir characterization using ensemble-based assimilation methods

Author

Saman Jahanbakhshi

Subjects

history matching, future performance, uncertainty quantification, ensemble-based assimilation, punq-s3 model, Mining engineering. Metallurgy, TN1-997

Abstract

Characterization of large reservoir models with a great number of uncertain parameters is frequently carried out by ensemble-based assimilation methods, due to their computational efficiency, ease of implementation, versatility, and non-necessity of adjoint code. In this study, multiple ensemble-based assimilation techniques are utilized to characterize the well-known PUNQ-S3 model. Accordingly, actual measurements are employed to determine porosity, horizontal and vertical permeabilities, and their associated uncertainties. In consequence, the uncertain parameters of the model will gradually be adapted toward the true values during the assimilation of actual measurements, including bottomhole pressure and production rates of the reservoir. Monotonic reduction of root-mean-squared error and capturing the key points of the maps (such as direction of anisotropy and porosity/permeability contrasts) verify successful estimation of the geostatistical properties of the PUNQ-S3 model during history matching. At the end of the assimilation process, the RMSE values for Deterministic Ensemble Kalman Filter, Ensemble Kalman Filter, Ensemble Kalman Filter with Bootstrap Regularization, Ensemble Transform Kalman Filter Symmetric Solution, Ensemble Transform Kalman Filter Random Rotation, and Singular Evolutive Interpolated Kalman filter are 1.120, 1.153, 1.132, 1.132, 1.129, and 1.113, respectively. In addition to RMSE, the quality of history match as well as prediction of future performance are looked into in order to assess the performance of the assimilation process. Obviously, the results of the ensemble-based assimilation methods closely match the true results both in the history match section and in the future prediction section. Besides, the uncertainty of future predictions is quantified using multiple history-matched realizations. This is due to the fact that Kalman-based filters use a Bayesian framework in the assimilation step. Accordingly, the updated ensemble members are samples of the posterior distribution through which the uncertainty of future performance is assessed.

Published

2023

28. Enhanced history matching process by incorporation of saturation logs as model selection criteria

Author

Jesus Manuel APONTE, Robert WEBBER, Maria Astrid CENTENO, Hom Nath DHAKAL, Mohamed Hassan SAYED, and Reza MALAKOOTI

Subjects

geological modeling, reservoir model, objective function, binary classification, history matching, saturation logs, Petroleum refining. Petroleum products, TP690-692.5

Abstract

This paper proposes a methodology for an alternative history matching process enhanced by the incorporation of a simplified binary interpretation of reservoir saturation logs (RST) as objective function. Incorporating fluids saturation logs during the history matching phase unlocks the possibility to adjust or select models that better represent the near wellbore waterfront movement, which is particularly important for uncertainty mitigation during future well interference assessments in water driven reservoirs. For the purposes of this study, a semi-synthetic open-source reservoir model was used as base case to evaluate the proposed methodology. The reservoir model represents a water driven, highly heterogenous sandstone reservoir from Namorado field in Brazil. To effectively compare the proposed methodology against the conventional methods, a commercial reservoir simulator was used in combination with a state-of-the-art benchmarking workflow based on the Big Loop™ approach. A well-known group of binary metrics were evaluated to be used as the objective function, and the Matthew correlation coefficient (MCC) has been proved to offer the best results when using binary data from water saturation logs. History matching results obtained with the proposed methodology allowed the selection of a more reliable group of reservoir models, especially for cases with high heterogeneity. The methodology also offers additional information and understanding of sweep behaviour behind the well casing at specific production zones, thus revealing full model potential to define new wells and reservoir development opportunities.

Published

2023

29. Well Deliverability Assessment of Libyan Near-Critical Gas Condensate Field

Author

Gadrbouh, Raghd, Khazam, Mohsen, Pisello, Anna Laura, Editorial Board Member, Hawkes, Dean, Editorial Board Member, Bougdah, Hocine, Editorial Board Member, Rosso, Federica, Editorial Board Member, Abdalla, Hassan, Editorial Board Member, Boemi, Sofia-Natalia, Editorial Board Member, Mohareb, Nabil, Editorial Board Member, Mesbah Elkaffas, Saleh, Editorial Board Member, Bozonnet, Emmanuel, Editorial Board Member, Pignatta, Gloria, Editorial Board Member, Mahgoub, Yasser, Editorial Board Member, De Bonis, Luciano, Editorial Board Member, Kostopoulou, Stella, Editorial Board Member, Pradhan, Biswajeet, Editorial Board Member, Abdul Mannan, Md., Editorial Board Member, Alalouch, Chaham, Editorial Board Member, Gawad, Iman O., Editorial Board Member, Nayyar, Anand, Editorial Board Member, Amer, Mourad, Series Editor, Çiner, Attila, editor, Banerjee, Santanu, editor, Lucci, Federico, editor, Radwan, Ahmed E., editor, Shah, Afroz Ahmad, editor, Doronzo, Domenico M., editor, Hamimi, Zakaria, editor, and Bauer, Wilfried, editor

Published

2023

30. Improving the economic recovery of oil and gas through data analysis and optimal flow measurement

Author

Sadri, Mahdi, Shariatipour, Seyed, Hunt, Andrew, Gaura, Elena, and Henry, Manus

Subjects

338.2, oil and gas, data analysis, flow measurement, reservoir management, allocation, machine learning, artificial neural network, reservoir simulation, modelling, uncertainty, hydrocarbon accounting, history matching, well testing

Abstract

Although our energy supply is not longed purely wedded to fossil fuels but produced from a wider range of sources such as solar or wind these days, there remains a considerable challenge in providing affordable and reliable energy to all households around the world. The oil and gas industry as the biggest supplier to address this demand for energy still plays the major role in the energy market and has an extensive influence on the energy price. Increasing the economic efficiency of the processes and the energy-producing systems in this industry can therefore significantly contribute to securing energy affordability. With the ever-increasing application of data in the oil and gas industry, its availability and accuracy are of vital importance in hydrocarbon field management and increasing the economic recovery of oil and gas. Perhaps the most important type of data in the oil and gas industry are production flow rates which is a basis of decisions in hydrocarbon field management. In many cases, however, the production data of wells contain large flow measurement uncertainties or are not available continuously due to the shortcomings of the traditional methods of flow measurement or estimation that are still used in the industry. This research has investigated the effects of these uncertainties on the economic recovery of oil and gas reservoirs and tried to propose solutions for mitigating them. In order to do that, the uncertainties in the production data have been statistically analysed and the effects of the frequency of flow tests on the accuracy of allocation calculations and hydrocarbon accounting have been investigated (Chapter 3). The case studies in the analysis showed up to 80 million dollars reduction in the annual cost of allocation uncertainties when flow tests were undertaken weekly instead of monthly in an oil field with 36 production wells. Based on the statistical analysis, a method that includes the application of an artificial neural network has been proposed to find the minimum frequency of flow tests required to achieve a desired allocation error (Chapter 4). The effects of the uncertainties of flow data on history matching and well testing (Chapter 5), which are two main exercises contributing to reservoir management, have been investigated subsequently. The results show the significance of the negative effect of systematic errors and therefore the importance of regular calibration and maintenance of flow meters, installing multi-phase flow meters on individual wells, and recording the data downhole instead of on the surface.

Published

2020

31. Uncertainty Quantification for complex computer models with nonstationary output : Bayesian optimal design for iterative refocussing

Author

Volodina, V. and Williamson, D.

Subjects

003, Uncertainty Quantification, History matching, Bayesian optimal design, Kernel mixture, Nonstationary Gaussian Processes, Emulation

Abstract

In this thesis, we provide the Uncertainty Quantification (UQ) tools to assist automatic and robust calibration of complex computer models. Our tools allow users to construct a cheap (statistical) surrogate, a Gaussian process (GP) emulator, based on a small number of climate model runs. History matching (HM), the calibration process of removing parameter space for which computer model outputs are inconsistent with the observations, is combined with an emulator. The remaining subset of parameter space is termed the Not Ruled Out Yet (NROY). A weakly stationary GP with a covariance function that depends on the distance between two input points is the principal tool in UQ. However, the stationarity assumption is inadequate when we operate with a heterogeneous model response. In this thesis, we develop diagnostic-led nonstationary GP emulators with a kernel mixture. We employ diagnostics from a stationary GP fit to identify input regions with distinct model behaviour and obtain mixing functions for a kernel mixture. The result is a continuous emulator in parameter space that adapts to changes in model response behaviour. History matching has proven to be more effective when performed in waves. At each wave of HM, a new ensemble is obtained to update an emulator before finding an NROY space. In this thesis, we propose a Bayesian experimental design with a loss function that compares the volume of the NROY space obtained with an updated emulator to the volume of the “true” NROY space obtained using a “perfect” emulator. We combine Bayesian Design Criterion with our proposed nonstationary GP emulator to perform calibration of climate model.

Published

2020

32. Applications of Machine Learning in Subsurface Reservoir Simulation—A Review—Part II.

Author

Samnioti, Anna and Gaganis, Vassilis

Subjects

*MACHINE learning, *DECISION making, *PETROLEUM industry, *GROUND penetrating radar

Abstract

In recent years, Machine Learning (ML) has become a buzzword in the petroleum industry, with numerous applications which guide engineers in better decision making. The most powerful tool that most production development decisions rely on is reservoir simulation with applications in multiple modeling procedures, such as individual simulation runs, history matching and production forecast and optimization. However, all of these applications lead to considerable computational time and computer resource-associated costs, rendering reservoir simulators as not fast and robust enough, and thus introducing the need for more time-efficient and intelligent tools, such as ML models which are able to adapt and provide fast and competent results that mimic the simulator's performance within an acceptable error margin. In a recent paper, the developed ML applications in a subsurface reservoir simulation were reviewed, focusing on improving the speed and accuracy of individual reservoir simulation runs and history matching. This paper consists of the second part of that study, offering a detailed review of ML-based Production Forecast Optimization (PFO). This review can assist engineers as a complete source for applied ML techniques in reservoir simulation since, with the generation of large-scale data in everyday activities, ML is becoming a necessity for future and more efficient applications. [ABSTRACT FROM AUTHOR]

Published

2023

33. Deep learning-aided image-oriented history matching of geophysical data.

Author

Zhang, Yanhui, Katterbauer, Klemens, Zhang, Tao, AlShehri, Abdallah A., and Hoteit, Ibrahim

Subjects

*DEEP learning, *CONVOLUTIONAL neural networks, *IMAGE registration, *WATERFRONTS, *IMAGE denoising, *FEATURE extraction, *IMAGE processing

Abstract

Various types of geophysical measurements have been made available to illuminate different characteristics of subsurface reservoir formations. It becomes crucial to both efficiently and effectively utilize the information contained in these measurements for enhanced reservoir characterization and more informative decision-making support. To address the problem, image-oriented history matching approaches were proposed, which have shown promising results in efficiently assimilating multiple types of geophysical measurements. Relying on the interpretability of geophysical measurements, image-oriented strategies seek to match the extracted features or patterns (e.g., water front positions from the inverted saturation field) instead of the original data in the model update step. Consequently, the quality of the extracted features directly impacts the performance of these methods. However, extracting reliable features from related geophysical data is not straightforward. It requires not only in-depth domain knowledge but also appropriate image processing techniques. This study explores the use of deep learning (DL) based image segmentation techniques as an alternative to assist the feature extraction for an image-oriented ensemble-based history matching workflow. Accounting for the special characteristics of the considered application, a fast unsupervised DL segmentation model based on the convolutional neural network (CNN) is used together with an image denoising algorithm. The developed workflow separates the history matching of geophysical data into two sequential steps. It starts with a (joint) geophysical inversion step for saturation mapping, followed by a featured-oriented assimilation step to match the inverted saturation field, in which water front positions are extracted using the DL-based segmentation model. We test the proposed workflow on a synthetic reservoir model to history match electromagnetic (EM) and seismic data, which illustrates its promising performance in extracting relevant information from the data for efficient history matching. [ABSTRACT FROM AUTHOR]

Published

2023

34. CO2 Geological Storage

Author

Sorai, Masao, Lei, Xinglin, Nishi, Yuji, Ishido, Tsuneo, Nakao, Shinsuke, Lackner, Maximilian, editor, Sajjadi, Baharak, editor, and Chen, Wei-Yin, editor

Published

2022

35. An Effective Method for History Matching and Production Forecast for Naturally Fractured Carbonate Reservoir

Author

Lv, Jianjiang, Van Vo, Minh, Su, San, Yu, Yue, Wu, Wei, Series Editor, and Lin, Jia'en, editor

Published

2022

36. An Integrated Method to Improve History Matching Efficiency and Quality of a Complicated Oilfield

Author

Liao, Chang-lin, Chen, Jing, Feng, Min, Yang, Xuan-yu, Huang, Qi-zhi, Wang, Min, Wu, Wei, Series Editor, and Lin, Jia'en, editor

Published

2022

37. Analysis of Historical Production Data for Reservoir Performance Prediction of X Oil Field

Author

Eita, Mohamed Yasser Mohamed Sabri Farag, Mohammed, Elhassan Mostafa Abdalla, and Lin, Jia'en, editor

Published

2022

38. Structural and shape reconstruction using inverse problems and machine learning techniques with application to hydrocarbon reservoirs

Author

Etienam, Clement, Theodoropoulos, Konstantinos, Villegas, Rossmary, and Babaei, Masoud

Subjects

519, Level set, History Matching, Ensemble Kalman Filter, Inverse problem, Machine Learning

Abstract

This thesis introduces novel ideas in subsurface reservoir model calibration known as History Matching in the reservoir engineering community. The target of history matching is to mimic historical pressure and production data from the producing wells with the output from the reservoir simulator for the sole purpose of reducing uncertainty from such models and improving confidence in production forecast. Ensemble based methods such as the Ensemble Kalman Filter (EnKF) and Ensemble Smoother with Multiple Data Assimilation (ES-MDA) as been proposed for history matching in literature. EnKF/ES-MDA is a Monte Carlo ensemble nature filter where the representation of the covariance is located at the mean of the ensemble of the distribution instead of the uncertain true model. In EnKF/ES-MDA calculation of the gradients is not required, and the mean of the ensemble of the realisations provides the best estimates with the ensemble on its own estimating the probability density. However, because of the inherent assumptions of linearity and Gaussianity of petrophysical properties distribution, EnKF/ES-MDA does not provide an acceptable history-match and characterisation of uncertainty when tasked with calibrating reservoir models with channel like structures. One of the novel methods introduced in this thesis combines a successive parameter and shape reconstruction using level set functions (EnKF/ES-MDA-level set) where the spatial permeability fields' indicator functions are transformed into signed distances. These signed distances functions (better suited to the Gaussian requirement of EnKF/ES-MDA) are then updated during the EnKF/ES-MDA inversion. The method outperforms standard EnKF/ES-MDA in retaining geological realism of channels during and after history matching and also yielded lower Root-Mean-Square function (RMS) as compared to the standard EnKF/ES-MDA. To improve on the petrophysical reconstruction attained with the EnKF/ES-MDA-level set technique, a novel parametrisation incorporating an unsupervised machine learning method for the recovery of the permeability and porosity field is developed. The permeability and porosity fields are posed as a sparse field recovery problem and a novel SELE (Sparsity-Ensemble optimization-Level-set Ensemble optimisation) approach is proposed for the history matching. In SELE some realisations are learned using the K-means clustering Singular Value Decomposition (K-SVD) to generate an overcomplete codebook or dictionary. This dictionary is combined with Orthogonal Matching Pursuit (OMP) to ease the ill-posed nature of the production data inversion, converting our permeability/porosity field into a sparse domain. SELE enforces prior structural information on the model during the history matching and reduces the computational complexity of the Kalman gain matrix, leading to faster attainment of the minimum of the cost function value. From the results shown in the thesis; SELE outperforms conventional EnKF/ES-MDA in matching the historical production data, evident in the lower RMS value and a high geological realism/similarity to the true reservoir model.

Published

2019

39. Reservoir characterization using ensemble-based assimilation methods.

Author

Jahanbakhshi, Saman

Subjects

*RESERVOIRS, *POROSITY, *STANDARD deviations, *KALMAN filtering, *BAYESIAN analysis, *PERMEABILITY

Abstract

Characterization of large reservoir models with a great number of uncertain parameters is frequently carried out by ensemble-based assimilation methods, due to their computational efficiency, ease of implementation, versatility, and non-necessity of adjoint code. In this study, multiple ensemble-based assimilation techniques are utilized to characterize the well-known PUNQ-S3 model. Accordingly, actual measurements are employed to determine porosity, horizontal and vertical permeabilities, and their associated uncertainties. In consequence, the uncertain parameters of the model will gradually be adapted toward the true values during the assimilation of actual measurements, including bottomhole pressure and production rates of the reservoir. Monotonic reduction of root-mean-squared error and capturing the key points of the maps (such as direction of anisotropy and porosity/permeability contrasts) verify successful estimation of the geostatistical properties of the PUNQ-S3 model during history matching. At the end of the assimilation process, the RMSE values for Deterministic Ensemble Kalman Filter, Ensemble Kalman Filter, Ensemble Kalman Filter with Bootstrap Regularization, Ensemble Transform Kalman Filter Symmetric Solution, Ensemble Transform Kalman Filter Random Rotation, and Singular Evolutive Interpolated Kalman filter are 1.120, 1.153, 1.132, 1.132, 1.129, and 1.113, respectively. In addition to RMSE, the quality of history match as well as prediction of future performance are looked into in order to assess the performance of the assimilation process. Obviously, the results of the ensemble-based assimilation methods closely match the true results both in the history match section and in the future prediction section. Besides, the uncertainty of future predictions is quantified using multiple history-matched realizations. This is due to the fact that Kalman-based filters use a Bayesian framework in the assimilation step. Accordingly, the updated ensemble members are samples of the posterior distribution through which the uncertainty of future performance is assessed. [ABSTRACT FROM AUTHOR]

Published

2023

40. Semi‐Automatic Tuning of Coupled Climate Models With Multiple Intrinsic Timescales: Lessons Learned From the Lorenz96 Model.

Author

Lguensat, Redouane, Deshayes, Julie, Durand, Homer, and Balaji, Venkatramani

Subjects

*ATMOSPHERIC models, *MACHINE learning, *EARTH (Planet), *CLIMATE extremes, *CLIMATE research

Abstract

The objective of this study is to evaluate the potential for History Matching (HM) to tune a climate system with multi‐scale dynamics. By considering a toy climate model, namely, the two‐scale Lorenz96 model and producing experiments in perfect‐model setting, we explore in detail how several built‐in choices need to be carefully tested. We also demonstrate the importance of introducing physical expertise in the range of parameters, a priori to running HM. Finally we revisit a classical procedure in climate model tuning, that consists of tuning the slow and fast components separately. By doing so in the Lorenz96 model, we illustrate the non‐uniqueness of plausible parameters and highlight the specificity of metrics emerging from the coupling. This paper contributes also to bridging the communities of uncertainty quantification, machine learning and climate modeling, by making connections between the terms used by each community for the same concept and presenting promising collaboration avenues that would benefit climate modeling research. Plain Language Summary: Climate models are computer simulation codes that incorporate centuries of human knowledge of the physics of planet Earth. They are used to understand the past, the present and make projections about the future of our climate. To validate a climate model, scientists tune a number of its parameters so that it yields a simulated climate resembling real‐life observations as much as possible. The main challenge in this tuning task is the extreme cost of climate models which limits a lot the number of tuning experiments scientists can run. In this paper we are interested in a technique that uses artificial intelligence in order to replace the expensive climate model with a cheaper surrogate. We experiment on a simplified model to assess the strengths and weaknesses of this semi‐automatic technique, and show that it can be more efficient when combined with human expertise. Key Points: The History Matching method is explained in detail then used for tuning a toy coupled model: the Lorenz 96 modelThe importance of several design choices is demonstrated, especially when considering forced experiments such as Atmospheric Model Intercomparison Protocol and Ocean Model Intercomparison ProjectWe argue that this tuning method is semi‐automatic & highlight the importance of human expertise when considering it for real coupled models [ABSTRACT FROM AUTHOR]

Published

2023

41. Enhanced history matching process by incorporation of saturation logs as model selection criteria.

Author

APONTE, Jesus Manuel, WEBBER, Robert, CENTENO, Maria Astrid, DHAKAL, Hom Nath, SAYED, Mohamed Hassan, and MALAKOOTI, Reza

Published

2023

42. Reservoir automatic history matching method using ensemble Kalman filter based on shrinkage covariance matrix estimation.

Author

Jing, Cao

Subjects

COVARIANCE matrices, HISTORY of technology, MIMO radar

Abstract

Because the geological conditions of the reservoir are complicated and involve many factors, the inversion of reservoir parameters is realized by using numerical simulation technology and history matching method. At present, Ensemble Kalman Filter method is widely used in history matching. But in the fact, the Ensemble Kalman Filter has problem such as inaccurate gradient calculation and pseudo correlation. In this paper, the Ensemble Kalman Filter based on shrinkage covariance matrix estimation is used to construct the localization matrix. By gradually matching production performance, the gradient of data assimilation method is corrected, the pseudo correlation is weakened, the reservoir model is updated, and the optimal estimate is obtained. By an example, we compare the Ensemble Kalman Filter and Ensemble Kalman Filter based on shrinkage covariance matrix estimation. The results show that Ensemble Kalman Filter based on shrinkage covariance matrix estimation is superior to Ensemble Kalman Filter in the accuracy of model production dynamic matching. [ABSTRACT FROM AUTHOR]

Published

2023

43. Semi‐Automatic Tuning of Coupled Climate Models With Multiple Intrinsic Timescales: Lessons Learned From the Lorenz96 Model

Author

Redouane Lguensat, Julie Deshayes, Homer Durand, and Venkatramani Balaji

Subjects

model tuning, Gaussian processes, surrogate modeling, history matching, Lorenz 96, uncertainty quantification, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract The objective of this study is to evaluate the potential for History Matching (HM) to tune a climate system with multi‐scale dynamics. By considering a toy climate model, namely, the two‐scale Lorenz96 model and producing experiments in perfect‐model setting, we explore in detail how several built‐in choices need to be carefully tested. We also demonstrate the importance of introducing physical expertise in the range of parameters, a priori to running HM. Finally we revisit a classical procedure in climate model tuning, that consists of tuning the slow and fast components separately. By doing so in the Lorenz96 model, we illustrate the non‐uniqueness of plausible parameters and highlight the specificity of metrics emerging from the coupling. This paper contributes also to bridging the communities of uncertainty quantification, machine learning and climate modeling, by making connections between the terms used by each community for the same concept and presenting promising collaboration avenues that would benefit climate modeling research.

Published

2023

44. Reservoir automatic history matching: Methods, challenges, and future directions.

Author

Piyang Liu, Kai Zhang, and Jun Yao

Subjects

*RESERVOIRS, *MACHINE learning, *ALGORITHMS, *FORECASTING, *DECISION making

Abstract

Reservoir history matching refers to the process of continuously adjusting the parameters of the reservoir model, so that its dynamic response will match the historical observation data, which is a prerequisite for making forecasts based on the reservoir model. With the development of optimization theory and machine learning algorithms, automatic history matching has made numerous breakthroughs for practical applications. In this perspective, the existing automatic history matching methods are summarized and divided into model-driven and surrogate-driven history matching methods according to whether the reservoir simulator needs to be run during the automatic history matching process. Then, the basic principles of these methods and their limitations in practical applications are outlined. Finally, the future trends of reservoir automatic history matching are discussed. [ABSTRACT FROM AUTHOR]

Published

2023

45. Testing the INSIM-FT Proxy Simulation Method.

Author

Ovsepian, Mkhitar, Lys, Egor, Cheremisin, Alexander, Frolov, Stanislav, Kurmangaliev, Rustam, Usov, Eduard, Ulyanov, Vladimir, Tailakov, Dmitry, and Kayurov, Nikita

Subjects

*INJECTION wells, *TEST methods

Abstract

This paper describes testing of the INSIM-FT proxy simulation method (interwell-numerical-simulation model improved with front-tracking method) to assess the dependencies between production and injection wells, as well as to assess the forecast of oil/liquid production by wells depending on their operation parameters. The paper proposes the approach of taking into account the influence of various production enhancement operations. The method was tested on a synthetic hydrodynamic model and on a sector of a real field. The results show a good match between historical data and simulation results and indicate significant computational efficiency compared to classical reservoir simulators. [ABSTRACT FROM AUTHOR]

Published

2023

46. Study on property evaluation and numerical simulation of air-foam flooding in low permeability reservoir.

Author

Yuan, Yingzhong, Yan, Wende, Qi, Zhilin, Luo, Taotao, and Fan, Wei

Subjects

*FOAM, *COMPUTER simulation, *PERMEABILITY, *POROUS materials, *FLOODS, *PHENOMENOLOGICAL theory (Physics)

Abstract

Comprehensively considering the migration law of air and foam in porous media, various physical and chemical phenomena, and the change of gas phase mobility are researched, then mathematical models of air-foam flooding are established. Based on air-foam flooding experiments, the relevant parameters of empirical model for numerical simulation of air-foam flooding were obtained. Matching of parallel core displacement experiment and air foam test flooding in Wuliwan Oilfield is completed with total fitting degree of more than 90%, and the reliability of empirical model of numerical simulation for air-foam flooding is verified. [ABSTRACT FROM AUTHOR]

Published

2023

47. Parallel Automatic History Matching Algorithm Using Reinforcement Learning.

Author

Alolayan, Omar S., Alomar, Abdullah O., and Williams, John R.

Subjects

*MARKOV processes, *ALGORITHMS, *REINFORCEMENT learning, *MATHEMATICAL optimization, *PATTERN matching, *PROBLEM solving, *ARTIFICIAL intelligence

Abstract

Reformulating the history matching problem from a least-square mathematical optimization problem into a Markov Decision Process introduces a method in which reinforcement learning can be utilized to solve the problem. This method provides a mechanism where an artificial deep neural network agent can interact with the reservoir simulator and find multiple different solutions to the problem. Such a formulation allows for solving the problem in parallel by launching multiple concurrent environments enabling the agent to learn simultaneously from all the environments at once, achieving significant speed up. [ABSTRACT FROM AUTHOR]

Published

2023

48. Developing a Coupled Static-Dynamic Algorithm for Optimization of Reservoir Characterization.

Author

Abollfazli, S. K., Tokhmechi, B., and Riabi, S. R. Ghavami

Subjects

*HYDROCARBON reservoirs, *FLUID flow, *PETROLEUM reservoirs, *COMPUTER programming, *DYNAMIC models

Abstract

Reservoir simulation is the combination of physics, mathematics, reservoir engineering, and computer programming for predicting the performance of a hydrocarbon reservoir under various operating conditions. The necessity of optimizing oil extraction methods is to increase the efficiency of a hydrocarbon reservoir under various operating conditions. Therefore, in a hydrocarbon recovery project that may involve hundreds of millions of dollars in investments, the risk associated with using the best method for the desired outcome must be evaluated and minimized. Finding an optimal model for static reservoir simulation through fluid flow model is the main goal of this paper. For this purpose, first of all, artificial data of porosity and permeability was generated, and then these data were used for geostatistical simulation. Sequential Gaussian Simulation (SGS) method was used for static simulation of a region and for each of two static parameters, 25 realizations were obtained. The realizations of SGS were randomly entered in the dynamic model of the reservoir. Dynamic model was coded by Python for slightly-compressible fluid flow equations in three dimensions and the pressure in each of the blocks in the oil production reservoir was determined. For each category, the least Sum of Squared Errors (SSE) was determined and then the corresponding static model was selected as the desired static model. With a reliable static model, it is possible to define different locations for designing injection and oil production wells, potential intelligent wells areas, as well as optimizing the management of a reservoir, which leads to costs reduction and, at the same time, increase in oil production. [ABSTRACT FROM AUTHOR]

Published

2023

49. Deep learning-based geological parameterization for history matching CO2 plume migration in complex aquifers.

Author

Feng, Li, Mo, Shaoxing, Sun, Alexander Y., Wang, Dexi, Yang, Zhengmao, Chen, Yuhan, Wang, Haiou, Wu, Jichun, and Shi, Xiaoqing

Subjects

*MACHINE learning, *CARBON dioxide, *LATENT variables, *PERMEABILITY, *AQUIFERS, *GAUSSIAN distribution, *DEEP learning

Abstract

History matching is crucial for reliable numerical simulation of geological carbon storage (GCS) in deep subsurface aquifers. This study focuses on inferring highly complex aquifer permeability fields with multi- and intra-facies heterogeneity to improve the characterization of CO 2 plume migration. We propose a deep learning (DL)-based parameterization strategy combined with the ensemble smoother with multiple data assimilation (ESMDA) algorithm to formulate an integrated inverse framework. The DL model is employed to parameterize non-Gaussian permeability fields using low-dimensional latent variables in a Gaussian distribution, thereby mitigating the non-Gaussianity issue faced by the ensemble-based ESMDA inverse method and simultaneously alleviating the computational burden of high-dimensional inversion. The efficacy of the integrated DL-ESMDA inverse framework is demonstrated using a 3-D GCS model, where it estimates the non-Gaussian permeability field characterized by multi- and intra-facies heterogeneity. Results show that the DL model is able to represent the highly complex and high-dimensional permeability fields using low-dimensional latent vectors. The DL-ESMDA framework sequentially updates these low-dimensional latent vectors instead of the original high-dimensional permeability field to obtain posterior estimations of the permeability field. The resulting CO 2 plume migration closely matches historical measurements, suggesting a significantly improved model reliability after history matching. Additionally, a substantial reduction in uncertainty for future plume migration predictions beyond the history matching period is observed. The proposed framework provides an effective approach for reliable characterization of CO 2 plume migration in highly heterogeneous aquifers, enhancing GCS project operation and risk analysis. • We propose a deep learning-enabled, data assimilation method for history matching CO 2 storage in non-Gaussian aquifers. • The deep learning algorithm is trained to represent permeability fields in low-dimensional space. • Non-Gaussianity of permeability is preserved while reducing the parameter dimension. • Predictive uncertainty of CO 2 plume migration is significantly reduced using our method. [ABSTRACT FROM AUTHOR]

Published

2024

50. An offline data-driven dual-surrogate framework considering prediction error for history matching.

Author

Zhang, Jinding, Zhang, Kai, Zhang, Liming, Zhou, Wensheng, Liu, Chen, Liu, Piyang, Fu, Wenhao, Chen, Xu, Bian, Ziwei, Yang, Yongfei, and Yao, Jun

Subjects

*CONVOLUTIONAL neural networks, *BIOLOGICAL evolution, *DEEP learning, *ERROR functions, *TIME series analysis, *DIFFERENTIAL evolution, *RECURRENT neural networks

Abstract

High computer power has long been a critical ingredient that affects the effectiveness and efficiency of history matching. Data-driven surrogate modeling as an efficient strategy can accelerate the history-matching process by constructing machine learning-based models with high computing speed but reduced accuracy. However, the applicability of surrogate models for different history-matching problems is uncertain due to the influence of data quality and quantity, model architectures, and hyperparameters. To overcome this issue, an offline data-driven dual-surrogate framework (ODDF) that considers the prediction error of surrogate models for history matching is proposed, where one surrogate model predicts the production data of reservoirs and the other one learns the prediction error of the former surrogate. The first surrogate model considers the time-series characteristics of production data using a recurrent neural network, while the second surrogate model regards the two-dimensional spatial correlation characteristics of multivariate prediction error using a fully convolutional neural network. Furthermore, an enhanced error model is applied to incorporate the prediction error into the objective function to reduce the influence of the prediction error on inversion results. Based on this hybrid framework, one can improve the prediction accuracy of surrogate models in history matching when the architectures or hyperparameters of surrogate models are not optimal. Additionally, one can obtain satisfactory results for history matching and uncertainty quantification based on surrogate modeling. The proposed framework is validated on the history matching of two- and three-dimensional reservoir models. The results show that the proposed method is robust in constructing the surrogate models and predicting the production data of reservoirs, which improves the efficiency and reliability of history matching. • A dual-surrogate framework is proposed for history matching to deal with the prediction error of imperfect surrogates. • Considering the time series and correlation of production data, the accuracy and robustness of surrogates are improved. • The prediction error of surrogates is incorporated into the objective function of history matching. • Combining the dual-surrogate framework with an adaptive differential evolution algorithm, the results are satisfactory. [ABSTRACT FROM AUTHOR]

Published

2024