Analysis of Production History for Unconventional Gas Reservoirs With Statistical Methods

Bhattacharya, Srimoyee; Nikolaou, Michael

doi:10.2118/147658-pa

Cited by 27 publications

(9 citation statements)

References 59 publications

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“…This is achieved by orthogonally transforming the dataset into a new set of uncorrelated variables or principal components, which are computed from eigenvalue decomposition of the covariance matrix (Smith, 2002). The PCA technique has been successfully applied in areas including history matching (Sarma, Durlofsky, Aziz, & Chen, 2007;Yadav, 2006), reservoir property estimation (Dadashpour, Rwechungura, & Kleppe, 2011;Lee, Kharghoria, & Datta-Gupta, 2002;Scheevel & Payrazyan, 2001), and production data analysis (Bhattacharya & Nikolaou, 2013).…”

Section: Related Workmentioning

confidence: 99%

Practical implementation of knowledge-based approaches for steam-assisted gravity drainage production analysis

Leung

Zanon

et al. 2015

Expert Systems with Applications

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Section: Related Workmentioning

confidence: 99%

Practical implementation of knowledge-based approaches for steam-assisted gravity drainage production analysis

Leung

Zanon

et al. 2015

Expert Systems with Applications

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“…Similar to the procedure outlined in Bhattacharya et al (2013) where multivariate PCA was used, functional principal component analysis also allows for production profile reconstruction, and dimensionality reduction. To reconstruct one production profile one has to sum products of principal components and associated scores and add such sum to the mean function computed on entire ensemble (fPCA, Ramsay et al 2005):…”

Section: Reconstructing Production Profiles With Fpcamentioning

confidence: 99%

“…The regression based forecasting framework outlined in Bhattacharya et al (2013), is another concept that can be extended into a functional context. Assuming that the mean function, and functional principal components are reasonably estimated from existing wells (training set), all that is needed to forecast production at some new well location are the functional principal component scores.…”

Section: Forecasting Frameworkmentioning

confidence: 99%

“…This is often challenging since production time series come as noisy, discrete observations of production rates over time. Conventional approaches to this problem rely on parameterizing the system with decline curves and work in the parameter space of the assumed decline model, or even simpler work with the raw data (Bhattacharya et al 2013). Here we take alternative non-parametric approach where we use the data to find the most appropriate smooth and continuous representation of declining production time series.…”

Section: Introductionmentioning

confidence: 99%

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Functional Approach to Data Mining, Forecasting, and Uncertainty Quantification in Unconventional Reservoirs

Grujic

Silva

Caers

2015

Day 3 Wed, September 30, 2015

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The difficulty in applying traditional reservoir simulation and modeling techniques for unconventional reservoir forecasting makes the use of statistical and modern machine learning techniques a relevant proposition for shale systems. However, the most current applications of these techniques often ignore the systematic time variations in production decline rates. Traditional decline curve modeling techniques fall short in predicting actual physical parameters and are highly dependent on the assumed physical model.In this paper, we propose a non-parametric statistical approach, more specifically, using a modern technique termed functional data analysis (FDA). In FDA production data is modeled as a time series composed of a sum of weighted smooth analytical basis functions. Instead of assuming a model, this technique allows us to learn the model from the data by jointly fitting all production profiles in the field. Principal component analysis can be applied to the functional data, termed (fPCA). Applying fPCA to declining rates from many wells, transforms time varying data into lower-dimensional score data. We found that in the real field data studied, 2-3 such functional principal components were sufficient to describe the entire production in a shale play. Low dimensional score data is also very valuable for data mining and sensitivities studies that enable better understanding of production drivers. Finally, building regressional relationships between geological and completions parameters and functional principal component scores enables forecasting production at new well locations with new sets of geological and completion parameters.Proposed methodology is demonstrated on a real reservoir case study with 172 horizontal and hydraulically fractured wells. Wells originate from one of the most prolific shale plays in North America, and have been in production for at least 500 days. Case study was focused on oil production rates, and obtained forecasting error over multiple test sets (100) was 21% (on average).

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“…The ability to use PCA to extract common trends and patterns from sets of data has made it applicable to production forecasting as well. Bhattacharya and Nikolaou [12] used PCA to analyze production history from unconventional gas reservoirs but did not forecast future production. Makinde and Lee [13] used the Principal Components Methodology (PCM) to forecast production from shale volatile oil reservoirs and compared the results to compositionally simulated data and production estimates from different decline curve analysis (DCA) models.…”

Section: Introductionmentioning

confidence: 99%

Statistical, Data-Driven Approach to Forecasting Production from Liquid-Rich Shale Reservoirs

Makinde¹

2017

OALib

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The oil and gas industry needs fast and simple techniques of forecasting oil and gas production. Forecasting production from unconventional, low permeability reservoirs is particularly challenging. As a contribution to the continuing efforts of finding solutions to this problem, this paper studies the use of a statistical, data-driven method of forecasting production from liquid-rich shale (LRS) reservoirs called the Principal Components Methodology (PCM). In this study, production of five different highly volatile and near-critical oil wells was simulated for 30 years with the aid of a commercial compositional simulator. Principal Components Methodology (PCM) was applied to production data from the representative wells by using Singular Value Decomposition (SVD) to calculate the principal components (PCs). These principal components were then used to forecast oil and solution gas production from the near-critical oil wells with production histories ranging from 0.5 to 2 years, and the results were compared to simulated data and the Modified Arps' decline model forecasts. Application of the PCM to field data is also included in this work. Various factors ranging from ultra-low permeability to multi-phase flow effects have plagued the mission of forecasting production from liquid rich shale reservoirs. Traditional decline curve analysis (DCA) methods have not been completely adequate for estimating production from shale reservoirs. The PCM method enables us to obtain the production decline structure that best captures the variance in the data from the representative wells considered. This technique eliminates the need for parameters like the hyperbolic decline exponents (b values) and the task of switching from one DCA model to another. Also, production forecasting can be done without necessarily using diagnostic plots. With PCM, production could be forecasted from liquid-rich shale reservoirs with reasonable certainty. This study presents an innovative and simple method of forecasting production from liquid-rich

show abstract

Analysis of Production History for Unconventional Gas Reservoirs With Statistical Methods

Cited by 27 publications

References 59 publications

Practical implementation of knowledge-based approaches for steam-assisted gravity drainage production analysis

Practical implementation of knowledge-based approaches for steam-assisted gravity drainage production analysis

Functional Approach to Data Mining, Forecasting, and Uncertainty Quantification in Unconventional Reservoirs

Statistical, Data-Driven Approach to Forecasting Production from Liquid-Rich Shale Reservoirs

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