Bootstrap Confidence Intervals for Reservoir Model Selection Techniques

1. Bootstrap Confidence Intervals for Reservoir Model Selection Techniques CélineScheidt and JefCaers SCRF Affiliate Meeting– April 30, 2009

2. Model Selection Techniques • Uncertaintyin reservoir modeling is represented through a possibly large setof reservoir models • Generated by varying several input parameters • High CPU demand for flow simulations requires the use of model selection techniques • Evaluate uncertainty on a subset of models • Model selection techniques select a subset of representative realizations which should preserve the statistics of the entire set of realizations • Eg.: Ranking, Distance-Kernel Method (DKM) SCRF Affiliate Meeting – 04/30/09

3. Goal • If we select N realizations, perform flow simulation, and quantify uncertainty: • How do we know if the results are accurate? • Can we be confident with the results? • Should we do more simulations? • We use of bootstrap methodology to evaluate the accuracy of the uncertainty quantification • Applicable to standard ranking or new distance-kernel method (DKM) SCRF Affiliate Meeting – 04/30/09

4. Model 1 Model 2 d12 d14 d13 d24 d32 d34 Model 4 Model 3 Distance Kernel Method (DKM) SCRF, 2008 SPE Journal, 2009 2D projection of Metric Space Distance Matrix D MDS M j Kernels P10,P50,P90 model selection 2D projection of Feature Space 2D projection of Metric Space Apply Clustering in F j-1 Pre-image F SCRF Affiliate Meeting – 04/30/09

5. Traditional Ranking Techinque • Generate a proxy response for each L realizations (ranking measure) • Should be strongly correlated to the actual response • Select N realizations for flow simulations • Traditionally, N=3 • Realizations equally spaced according to the ranking measure • Estimation of the distribution of the response using the N simulations • Compute P10, P50 and P90 statistics SCRF Affiliate Meeting – 04/30/09

6. Review: Parametric Bootstrap – Simple Example ? B bootstrap estimates of the mean and variance 1st estimate b = 1,..,B 2nd estimate SCRF Affiliate Meeting – 04/30/09

7. Notations • : Proxy response (ranking measure) • Eg. Streamline simulations • : True response • Eg. Eclipse simulations • : Selected realizations by model selection • : estimate of P10, P50 and P90 values • From ranking or DKM & flow simulation (1st estimate) • : bootstrap estimate of P10, P50 and P90 values • From ranking or DKM & parametric distribution (2nd estimate) No additional flow simulations SCRF Affiliate Meeting – 04/30/09

8. Proposed Bootstrap Methodology Application to model selection technique Proxy Values Model selection + flow simulation b = 1,…,B Model selection + response evaluation SCRF Affiliate Meeting – 04/30/09

9. Illustration: Bivariate Gaussian Distribution • Distribution of the target and proxy responses: • Proposed bootstrap technique applied for several correlation scenarios between target and proxy responses • Scenarios for: • rxy= 1, 0.9, 0.8, 0.7, 0.6,0.5 r = 0.9 SCRF Affiliate Meeting – 04/30/09

10. Histograms of the Estimated Quantiles • L= 100, r = 0.9 • Selection of 15 realizations using DKM • Number of bootstrap samples: B = 1000 Bootstrap estimated P90 Bootstrap estimated P50 Bootstrap estimated P10 Estimated P50 Estimated P10 Estimated P90 SCRF Affiliate Meeting – 04/30/09

11. Definition of the Error on the Bootstrap Estimated Quantiles • For each of the B samples, a dimensionless error is defined to evaluate the accuracy of the estimated quantiles: Error on bootstrap estimated quantiles:

12. Bivariate Gaussian distribution Confidence Intervals for different correlations scenarios r = 0.8 r = 0.9 r = 1.0 r = 0.5 r = 0.7 r = 0.6 SCRF Affiliate Meeting – 04/30/09

13. West Coast African Reservoir (WCA) Courtesy of Chevron • WCA is a deepwater turbidite offshore reservoir located in a slope valley • Dimensions of the reservoir model • 78 x 59 x 116 gridblocks • 100,000 active gridblocks • 28 wells • 20 production wells (red) • 8 injection wells (blue) 1 mile 0.5 mile 800 feet SCRF Affiliate Meeting – 04/30/09

14. West Coast African Reservoir • 4 depositional facies • Facies 1: Shale (55% of the reservoir) • Facies 2: Poor quality sand #1 (debris flows or levees) • Facies 3: Poor quality sand #2 (debris flows or levees) • Facies 4: Good quality channels (28 %) • Porosity for each facies determined by SGS conditioned to well data • Vshale for each facies modeled by SGS correlated to porosity • Permeability calculated analytically from Vshale SCRF Affiliate Meeting – 04/30/09

15. Uncertainty in Reservoir Description • Uncertainty exists for: • Depositional environment • Modeled using 12 training images (TI) & snesim • Facies proportions • Modeled with 3 different probability cubes • Probability cubes come from seismic • 2 realizations were generated for each combination of TI and facies probability cube • 72 possible realizations of the WCA reservoir SCRF Affiliate Meeting – 04/30/09

16. Definition of the Responses • True response X: • Cumulative oil production after 1200 days of production (evaluated by full flow simulation) • Proxy response Y: • Cumulative oil production after 1215 days of production (evaluated by fast streamline simulation) • Correlation coefficient: r(X,Y) = 0.92 SCRF Affiliate Meeting – 04/30/09

17. Definition of Distribution Function • Parametric bootstrap requires an assumption of the bivariate distribution function ( ) • Not known a priori in real case (contrary to previous example) • Use of a smoothing technique to obtain the distribution of the N selected bivariate samples True and proxy responses on the N Selected points SCRF Affiliate Meeting – 04/30/09

18. Generation of Bootstrap Samples Proxy measure (Streamline) Flow simulations (Chears) on N selected realizations 1stModel Selection to select N real. Sampling to generate new bivariate bootstrap datasets Smoothing on N selected realizations Bivariate response B times 2ndModel Selection to select N real. SCRF Affiliate Meeting – 04/30/09

19. Application of Bootstrap to WCA • Distance (for DKM only) • Difference in proxy response for every pair of realizations • Comparison between 3 model selection methods: • DKM, ranking and random selection • Selection of N realizations: N = 3,5,8,10,15,20 • The set of selected realizations are different for each N • Number of new bootstrap data sets generated: • B = 1000 SCRF Affiliate Meeting – 04/30/09

20. Bootstrap Estimated P10, P50 and P90 Quantiles SCRF Affiliate Meeting – 04/30/09

21. Error on Bootstrap Quantiles Estimations 10 simulations 5 simulations 20 simulations 15 simulations SCRF Affiliate Meeting – 04/30/09

22. Error on Bootstrap Quantiles Estimations • N = 8 or 10 simulations should be sufficient to obtain an accurate uncertainty quantification • Previous work (SCRF 2008) showed that with 7 simulations, uncertainty quantification on cumulative oil production was very accurate SCRF Affiliate Meeting – 04/30/09

23. Comparison of the Results to the “Truth” N = 8 N = 3 8 simulations 3 simulations

24. Conclusion • We have established a workflow to construct confidence intervals for quantile estimations • Workflow uses any model selection technique and parametric bootstrap procedure • DKM provides more robust results and outperforms ranking • The magnitude of the confidence intervals can show if more simulations are required for a better uncertainty quantification • Does not suggest how many more, only if sufficiently accurate SCRF Affiliate Meeting – 04/30/09