Locality-based 3-D multiple-point statistics reconstruction using 2-D geological cross sections

Hydrology and Earth System Sciences - Tập 22 Số 12 - Trang 6547-6566
Qiyu Chen1,2, Grégoire Mariethoz2, Gang Liu1, Alessandro Comunian3, Xiaogang Ma4
1Hubei Key Laboratory of Intelligent Geo-Information Processing, China University of Geosciences, Wuhan 430074, China
2Institute of Earth Surface Dynamics. University of Lausanne, 1015 Lausanne, Switzerland
3Dipartimento di Scienze della Terra “A. Desio”, Università degli Studi di Milano, Milan, Italy
4Department of Computer Science, University of Idaho, 875 Perimeter Drive MS 1010, Moscow, ID 83844-1010, USA

Tóm tắt

Abstract. Multiple-point statistics (MPS) has shown promise in representing complicated subsurface structures. For a practical three-dimensional (3-D) application, however, one of the critical issues is the difficulty in obtaining a credible 3-D training image. However, bidimensional (2-D) training images are often available because established workflows exist to derive 2-D sections from scattered boreholes and/or other samples. In this work, we propose a locality-based MPS approach to reconstruct 3-D geological models on the basis of such 2-D cross sections (3DRCS), making 3-D training images unnecessary. Only several local training subsections closer to the central uninformed node are used in the MPS simulation. The main advantages of this partitioned search strategy are the high computational efficiency and a relaxation of the stationarity assumption. We embed this strategy into a standard MPS framework. Two probability aggregation formulas and their combinations are used to assemble the probability density functions (PDFs) from different subsections. Moreover, a novel strategy is adopted to capture more stable PDFs, where the distances between patterns and flexible neighborhoods are integrated on multiple grids. A series of sensitivity analyses demonstrate the stability of the proposed approach. Several hydrogeological 3-D application examples illustrate the applicability of the 3DRCS approach in reproducing complex geological features. The results, in comparison with previous MPS methods, show better performance in portraying anisotropy characteristics and in CPU cost.

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Tài liệu tham khảo

Allard, D., Comunian, A., and Renard, P.: Probability aggregation methods in geoscience, Math. Geosci., 44, 545–581, 2012.

Arpat, G. B. and Caers, J.: Conditional simulation with patterns, Math. Geol., 39, 177–203, 2007.

Bayer, P., Huggenberger, P., Renard, P., and Comunian, A.: Three-dimensional high resolution fluvio-glacial aquifer analog: Part 1: Field study, J. Hydrol., 405, 1–9, 2011.

Bayer, P., Comunian, A., Höyng, D., and Mariethoz, G.: High resolution multi-facies realizations of sedimentary reservoir and aquifer analogs, Scient. Data, 2, 150033, https://doi.org/10.1038/sdata.2015.33, 2015.

Bordley, R. F.: A multiplicative formula for aggregating probability assessments, Manage. Sci., 28, 1137–1148, 1982.

Caers, J.: Geostatistical reservoir modelling using statistical pattern recognition, J. Petrol. Sci. Eng., 29, 177–188, 2001.

Caers, J.: Modeling uncertainty in the earth sciences, Wiley, Hoboken, 2011.

Caumon, G., Collon-Drouaillet, P., De Veslud, C. L. C., Viseur, S., and Sausse, J.: Surface-based 3-D modeling of geological structures, Math. Geosci., 41, 927–945, 2009.

Chen, Q.: A executable program of 3DRCS and test data, available at: http://www.escience.cn/people/chenqiyu/index.html, last access: 20 December 2018.

Chen, Q., Liu, G., Li, X., Zhang, Z., and Li, Y.: A corner-point-grid-based voxelization method for the complex geological structure model with folds, J. Visualizat., 20, 875–888, 2017.

Chen, Q., Liu, G., Ma, X., Mariethoz, G., He, Z., Tian, Y., and Weng, Z.: Local curvature entropy-based 3D terrain representation using a comprehensive Quadtree, ISPRS J. Photogram. Remote Sens., 139, 30–45, 2018.

Chugunova, T. L. and Hu, L. Y.: Multiple-point simulations constrained by continuous auxiliary data, Math. Geosci., 40, 133–146, 2008.

Comunian, A., Renard, P., Straubhaar, J., and Bayer, P.: Three-dimensional high resolution fluvio-glacial aquifer analog – Part 2: Geostatistical modeling, J. Hydrol., 405, 10–23, 2011.

Comunian, A., Renard, P., and Straubhaar, J.: 3-D multiple-point statistics simulation using 2-D training images, Comput. Geosci., 40, 49–65, 2012.

Comunian, A., Jha, S. K., Giambastiani, B. M. S., Mariethoz, G., and Kelly, B. F. J.: Training Images from Process-Imitating Methods, Math. Geosci., 46, 241–260, 2014.

Dai, Z., Ritzi, R. W., and Dominic, D. F.: Improving permeability semivariograms with transition probability models of hierarchical sedimentary architecture derived from outcrop analog studies, Water Resour. Res., 41, W07032, https://doi.org/10.1029/2004WR003515, 2005.

Dell Arciprete, D., Bersezio, R., Felletti, F., Giudici, M., Comunian, A., and Renard, P.: Comparison of three geostatistical methods for hydrofacies simulation: a test on alluvial sediments, Hydrogeol. J., 20, 299–311, 2012.

de Marsily, G., Delay, F., Gonçalvès, J., Renard, P., Teles, V., and Violette, S.: Dealing with spatial heterogeneity, Hydrogeol. J., 13, 161–183, 2005.

Deutsch, C. V. and Tran, T. T.: FLUVSIM: a program for object-based stochastic modeling of fluvial depositional systems, Comput. Geosci., 28, 525–535, 2002.

de Vries, L. M., Carrera, J., Falivene, O., Gratacós, O., and Slooten, L. J.: Application of multiple point geostatistics to non-stationary images, Math. Geosci., 41, 29–42, 2009.

Feyen, L. and Caers, J.: Multiple-point geostatistics: a powerful tool to improve groundwater flow and transport predictions in multi-modal formations, in: GeoENV V: Geostatistics for Environmental Applications, edited by: Renard, P., Demougeot-Renard, H., Froidevaux, R., Springer, Berlin, Heidelberg, 197–208, 2004.

Foged, N., Marker, P. A., Christansen, A. V., Bauer-Gottwein, P., Jørgensen, F., Høyer, A.-S., and Auken, E.: Large-scale 3-D modeling by integration of resistivity models and borehole data through inversion, Hydrol. Earth Syst. Sci., 18, 4349–4362, https://doi.org/10.5194/hess-18-4349-2014 2014.

Gaud, M. N., Smith, G. A., and McKenna, S. A.: Relating small-scale permeability heterogeneity to lithofacies distribution, in: Aquifer Characterization, edited by: Bridge, J. and Hyndman, D. W., Special Publication, SEPM, 55–66, 2004.

Genest, C. and Zidek, J. V.: Combining probability distributions: A critique and an annotated bibliography, Stat. Sci., 1, 114–135, 1986.

Guardiano, F. B. and Srivastava, R. M.: Multivariate geostatistics: beyond bivariate moments, in: Geostatistics Troia'92, Springer Netherlands, 133–144, 1993.

Gueting, N., Caers, J., Comunian, A., Vanderborght, J., and Englert, A.: Reconstruction of three-dimensional aquifer heterogeneity from two-dimensional geophysical data, Math. Geosci., 50, 53–75, 2017.

Hajizadeh, A., Safekordi, A., and Farhadpour, F. A.: A multiple-point statistics algorithm for 3-D pore space reconstruction from 2-D images, Adv. Water Resour., 34, 1256–1267, 2011.

He, X. L., Sonnenborg, T. O., Jørgensen, F., and Jensen, K. H.: The effect of training image and secondary data integration with multiple-point geostatistics in groundwater modelling, Hydrol. Earth Syst. Sci., 18, 2943–2954, https://doi.org/10.5194/hess-18-2943-2014, 2014.

Heinz, J., Kleineidam, S., Teutsch, G., and Aigner, T.: Heterogeneity patterns of Quaternary glaciofluvial gravel bodies (SW-Germany): application to hydrogeology, Sediment. Geol., 158, 1–23, 2003.

Hermans, T., Nguyen, F., and Caers, J.: Uncertainty in training image-based inversion of hydraulic head data constrained to ERT data: Workflow and case study, Water Resour. Res., 51, 5332–5352, 2015.

Hoffman, B. T. and Caers, J.: History matching by jointly perturbing local facies proportions and their spatial distribution: Application to a North Sea reservoir, J. Petrol. Sci. Eng., 57, 257–272, 2007.

Høyer, A.-S., Vignoli, G., Hansen, T. M., Vu, L. T., Keefer, D. A., and Jørgensen, F.: Multiple-point statistical simulation for hydrogeological models: 3-D training image development and conditioning strategies, Hydrol. Earth Syst. Sci., 21, 6069–6089, https://doi.org/10.5194/hess-21-6069-2017, 2017.

Hu, L. Y. and Chugunova, T.: Multiple-point geostatistics for modeling subsurface heterogeneity: A comprehensive review, Water Resour. Res., 44, W11413, https://doi.org/10.1029/2008WR006993, 2008.

Hu, R., Brauchler, R., Herold, M., and Bayer, P.: Hydraulic tomography analog outcrop study: Combining travel time and steady shape inversion, J. Hydrol., 409, 350–362, 2011.

Huysmans, M., Orban, P., Cochet, E., Possemiers, M., Ronchi, B., Lauriks, K., Batelaan, O., and Dassargues, A.: Using multiple-point geostatistics for tracer test modeling in a clay-drape environment with spatially variable conductivity and sorption coefficient, Math. Geosci., 46, 519–537, 2014.

Jackson, M. D., Percival, J. R. , Mostaghiml, P., Tollit, B. S., Pavlidis, D., Pain, C. C., Gomes, J. L. M. A., El-Sheikh, A. H., Salinas, P., Muggeridge, A. H., and Blunt, M. J.: Reservoir modeling for flow simulation by use of surfaces, adaptive unstructured meshes, and an overlapping-control-volume finite-element method, SPE Reserv. Eval. Eng., 18, 115–132, 2015.

Jha, S. K., Comunian, A., Mariethoz, G., and Kelly, B. F. J.: Parameterization of training images for aquifer 3-D facies modeling integrating geological interpretations and statistical inference, Water Resour. Res., 50, 7731–7749, 2014.

Journel, A. G.: Combining knowledge from diverse sources: An alternative to traditional data independence hypotheses, Math. Geol., 34, 573–596, 2002.

Kessler, T. C., Comunian, A., Oriani, F., Renard, P., Nilsson, B., Klint, K. E., and Bjerg, P. L.: Modeling Fine-Scale Geological Heterogeneity-Examples of Sand Lenses in Tills, Ground Water, 51, 692–705, 2013.

Klise, K. A., Weissmann, G. S., McKenna, S. A., Nichols, E. M., Frechette, J. D., Wawrzyniec, T. F., and Tidwell, V. C.: Exploring solute transport and streamline connectivity using lidar-based outcrop images and geostatistical representations of heterogeneity, Water Resour. Res., 45, W05413, https://doi.org/10.1029/2008WR007500, 2009.

Knudby, C. and Carrera, J.: On the relationship between indicators of geostatistical, flow and transport connectivity, Adv. Water Resour., 28, 405–421, 2005.

Krishnan, S.: The Tau Model for Data Redundancy and Information Combination in Earth Sciences: Theory and Application, Math. Geosci., 40, 705–727, 2008.

Maharaja, A.: TiGenerator: Object-based training image generator, Comput. Geosci., 34, 1753–1761, 2008.

Mahmud, K., Mariethoz, G., Baker, A., and Sharma, A.: Integrating multiple scales of hydraulic conductivity measurements in training image-based stochastic models, Water Resour. Res., 51, 465–480, 2015.

Mariethoz, G. and Kelly, B. F. J.: Modeling complex geological structures with elementary training images and transform-invariant distances, Water Resour. Res., 47, W07527, https://doi.org/10.1029/2011WR010412, 2011.

Mariethoz, G. and Renard, P.: Reconstruction of incomplete data sets or images using direct sampling, Math. Geosci., 42, 245–268, 2010.

Mariethoz, G., Renard, P., and Froidevaux, R.: Integrating collocated auxiliary parameters in geostatistical simulations using joint probability distributions and probability aggregation, Water Resour. Res., 45, W08421, https://doi.org/10.1029/2008WR007408, 2009.

Mariethoz, G., Renard, P., and Straubhaar, J.: The Direct Sampling method to perform multiple-point geostatistical simulations, Water Resour. Res., 46, W11536, https://doi.org/10.1029/2008WR007621, 2010.

Mariethoz, G., Straubhaar, J., Renard, P., Chugunova, T., and Biver, P.: Constraining distance-based multipoint simulations to proportions and trends, Environ. Model. Softw., 72, 184–197, 2015.

Meerschman, E., Pirot, G., Mariethoz, G., Straubhaar, J., Van Meirvenne, M., and Renard, P.: A practical guide to performing multiple-point statistical simulations with the Direct Sampling algorithm, Comput. Geosci., 52, 307–324, 2013.

Nichols, E. M., Weissmann, G. S., Wawrzyniec, T. F., Frechette, J. D., and Klise, K. A.: Processing of outcrop-based lidar imagery to characterize heterogeneity for groundwater models, SEPM Concepts Sediment. Paleontol., 10, 239–247, 2011.

Okabe, H. and Blunt, M. J.: Pore space reconstruction of vuggy carbonates using microtomography and multiple-point statistics, Water Resour. Res., 43, W12S02, https://doi.org/10.1029/2006WR005680, 2007.

Oriani, F., Straubhaar, J., Renard, P., and Mariethoz, G.: Simulation of rainfall time series from different climatic regions using the direct sampling technique, Hydrol. Earth Syst. Sci., 18, 3015–3031, https://doi.org/10.5194/hess-18-3015-2014, 2014.

Park, H., Scheidt, C., Fenwick, D., Boucher, A., and Caers J.: History matching and uncertainty quantification of facies models with multiple geological interpretations, Comput. Geosci., 17, 609–621, 2013.

Pickel, A., Frechette, J. D., Comunian, A., and Weissmann, G. S.: Building a training image with Digital Outcrop Models, J. Hydrol., 531, 53–61, 2015.

Pirot, G., Straubhaar, J., and Renard, P.: A pseudo genetic model of coarse braided-river deposits, Water Resour. Res., 51, 9595–9611, 2015.

Pyrcz, M. J. and Deutsch, C. V.: Geostatistical reservoir modeling, Oxford University Press, Oxford, 2014.

Pyrcz, M. J., Boisvert, J. B., and Deutsch, C. V.: ALLUVSIM: A program for event-based stochastic modeling of fluvial depositional systems, Comput. Geosci., 35, 1671–1685, 2009.

Raiber, M., White, P. A., Daughney, C. J., Tschritter, C., Davidson, P., and Bainbridge, S. E.: Three-dimensional geological modelling and multivariate statistical analysis of water chemistry data to analyse and visualise aquifer structure and groundwater composition in the Wairau Plain, Marlborough District, New Zealand, J. Hydrol., 436–437, 13–34, 2012.

Renard, P. and Allard, D.: Connectivity metrics for subsurface flow and transport, Adv. Water Resour., 51, 168–196, 2013.

Ritzi, R. W.: Behavior of indicator variograms and transition probabilities in relation to the variance in lengths of hydrofacies, Water Resour. Res., 36, 3375–3381, 2000.

Stone, M.: The opinion pool, Ann. Math. Stat., 32, 1339–1342, 1961.

Straubhaar, J., Renard, P., Mariethoz, G., Froidevaux, R., and Besson, O.: An improved parallel multiple-point algorithm using a list approach, Math. Geosci., 43, 305–328, 2011.

Strebelle, S.: Conditional simulation of complex geological structures using multiple-point statistics, Math. Geol., 34, 1–21, 2002.

Tahmasebi, P., Hezarkhani, A., and Sahimi, M.: Multiple-point geostatistical modeling based on the cross-correlation functions, Comput. Geosci., 16, 779–797, 2012.

Tan, X., Tahmasebi, P., and Caers, J.: Comparing training-image based algorithms using an analysis of distance, Math. Geosci., 46, 149–169, 2014.

Tran, T. T.: Improving variogram reproduction on dense simulation grids, Comput. Geosci., 20, 1161–1168, 1994.

Vassena, C., Cattaneo, L., and Giudici, M.: Assessment of the role of facies heterogeneity at the fine scale by numerical transport experiments and connectivity indicators, Hydrogeol. J., 18, 651–668, 2010.

Wambeke, T. and Benndorf, J.: An integrated approach to simulate and validate orebody realizations with complex trends: A case study in heavy mineral sands, Math. Geosci., 48, 767–789, 2016.

Weissmann, G. S., Carle, S. F., and Fogg, G. E.: Three-dimensional hydrofacies modeling based on soil surveys and transition probability geostatistics, Water Resour. Res., 35, 1761–1770, 1999.

Weissmann, G. S., Pickel, A., McNamara, K. C., Frechette, J. D., Kalinovich, I., Allen-King, R. M., and Jankovic, I.: Characterization and quantification of aquifer heterogeneity using outcrop analogs at the Canadian Forces Base Borden, Ontario, Canada, Geol. Soc. Am. Bull., 127, 1021–1035, 2015.

Wu, J., Boucher, A., and Zhang, T.: A SGeMS code for pattern simulation of continuous and categorical variables: FILTERSIM, Comput. Geosci., 34, 1863–1876, 2008.

Wu, K., Van Dijke, M. I. J., Couples, G. D., Jiang, Z., Ma, J., Sorbie, K. S., Crawford, J., Young, I., and Zhang, X.: 3-D stochastic modelling of heterogeneous porous media – Applications to reservoir rocks, Transp. Porous Media, 65, 443–467, 2006.

Yang, L., Hou, W., Cui, C., and Cui, J.: GOSIM: A multi-scale iterative multiple-point statistics algorithm with global optimization, Comput. Geosci., 89, 57–70, 2016.

Zappa, G., Bersezio, R., Felletti, F., and Giudici, M.: Modeling heterogeneity of gravel-sand, braided stream, alluvial aquifers at the facies scale, J. Hydrol., 325, 134–153, 2006.

Zhang, T., Switzer, P., and Journel, A.: Filter-based classification of training image patterns for spatial simulation, Math. Geol., 38, 63–80, 2006.

Zhang, T., Li, D., Lu, D., and Yang, J.: Research on the reconstruction method of porous media using multiple-point geostatistics, Science China Phys. Mech. Astron., 53, 122–134, 2010.

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Hydrology and Earth System Sciences

Tập 22 Số 12

6547-6566

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