Training Images from Process-Imitating Methods: An Application to the Lower Namoi Aquifer, Murray-Darling Basin, Australia

The lack of a suitable training image is one of the main limitations of the application of multiple-point statistics (MPS) for the characterization of heterogeneity in real case studies. Process-imitating facies modeling techniques can potentially provide training images. However, the parameterizati...

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Veröffentlicht in:	Mathematical geosciences 2014-02, Vol.46 (2), p.241-260
Hauptverfasser:	Comunian, Alessandro, Jha, Sanjeev K., Giambastiani, Beatrice M. S., Mariethoz, Gregoire, Kelly, Bryce F. J.
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Schlagworte:	Algorithms Aquifers Chemistry and Earth Sciences Computer based modeling Computer Science Computer simulation Earth and Environmental Science Earth Sciences Geology Geostatistics Geotechnical Engineering & Applied Earth Sciences Groundwater management Heterogeneity Hydrogeology Mathematical models Parametrization Physics Rivers Simulation Special Issue Statistics for Engineering Training
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creator	Comunian, Alessandro Jha, Sanjeev K. Giambastiani, Beatrice M. S. Mariethoz, Gregoire Kelly, Bryce F. J.
description	The lack of a suitable training image is one of the main limitations of the application of multiple-point statistics (MPS) for the characterization of heterogeneity in real case studies. Process-imitating facies modeling techniques can potentially provide training images. However, the parameterization of these process-imitating techniques is not straightforward. Moreover, reproducing the resulting heterogeneous patterns with standard MPS can be challenging. Here the statistical properties of the paleoclimatic data set are used to select the best parameter sets for the process-imitating methods. The data set is composed of 278 lithological logs drilled in the lower Namoi catchment, New South Wales, Australia. A good understanding of the hydrogeological connectivity of this aquifer is needed to tackle groundwater management issues. The spatial variability of the facies within the lithological logs and calculated models is measured using fractal dimension, transition probability, and vertical facies proportion. To accommodate the vertical proportions trend of the data set, four different training images are simulated. The grain size is simulated alongside the lithological codes and used as an auxiliary variable in the direct sampling implementation of MPS. In this way, one can obtain conditional MPS simulations that preserve the quality and the realism of the training images simulated with the process-imitating method. The main outcome of this study is the possibility of obtaining MPS simulations that respect the statistical properties observed in the real data set and honor the observed conditioning data, while preserving the complex heterogeneity generated by the process-imitating method. In addition, it is demonstrated that an equilibrium of good fit among all the statistical properties of the data set should be considered when selecting a suitable set of parameters for the process-imitating simulations.
doi_str_mv	10.1007/s11004-013-9505-y
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S.</creatorcontrib><creatorcontrib>Mariethoz, Gregoire</creatorcontrib><creatorcontrib>Kelly, Bryce F. J.</creatorcontrib><title>Training Images from Process-Imitating Methods: An Application to the Lower Namoi Aquifer, Murray-Darling Basin, Australia</title><title>Mathematical geosciences</title><addtitle>Math Geosci</addtitle><description>The lack of a suitable training image is one of the main limitations of the application of multiple-point statistics (MPS) for the characterization of heterogeneity in real case studies. Process-imitating facies modeling techniques can potentially provide training images. However, the parameterization of these process-imitating techniques is not straightforward. Moreover, reproducing the resulting heterogeneous patterns with standard MPS can be challenging. Here the statistical properties of the paleoclimatic data set are used to select the best parameter sets for the process-imitating methods. The data set is composed of 278 lithological logs drilled in the lower Namoi catchment, New South Wales, Australia. A good understanding of the hydrogeological connectivity of this aquifer is needed to tackle groundwater management issues. The spatial variability of the facies within the lithological logs and calculated models is measured using fractal dimension, transition probability, and vertical facies proportion. To accommodate the vertical proportions trend of the data set, four different training images are simulated. The grain size is simulated alongside the lithological codes and used as an auxiliary variable in the direct sampling implementation of MPS. In this way, one can obtain conditional MPS simulations that preserve the quality and the realism of the training images simulated with the process-imitating method. The main outcome of this study is the possibility of obtaining MPS simulations that respect the statistical properties observed in the real data set and honor the observed conditioning data, while preserving the complex heterogeneity generated by the process-imitating method. 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S.</au><au>Mariethoz, Gregoire</au><au>Kelly, Bryce F. J.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Training Images from Process-Imitating Methods: An Application to the Lower Namoi Aquifer, Murray-Darling Basin, Australia</atitle><jtitle>Mathematical geosciences</jtitle><stitle>Math Geosci</stitle><date>2014-02-01</date><risdate>2014</risdate><volume>46</volume><issue>2</issue><spage>241</spage><epage>260</epage><pages>241-260</pages><issn>1874-8961</issn><eissn>1874-8953</eissn><abstract>The lack of a suitable training image is one of the main limitations of the application of multiple-point statistics (MPS) for the characterization of heterogeneity in real case studies. Process-imitating facies modeling techniques can potentially provide training images. However, the parameterization of these process-imitating techniques is not straightforward. Moreover, reproducing the resulting heterogeneous patterns with standard MPS can be challenging. Here the statistical properties of the paleoclimatic data set are used to select the best parameter sets for the process-imitating methods. The data set is composed of 278 lithological logs drilled in the lower Namoi catchment, New South Wales, Australia. A good understanding of the hydrogeological connectivity of this aquifer is needed to tackle groundwater management issues. The spatial variability of the facies within the lithological logs and calculated models is measured using fractal dimension, transition probability, and vertical facies proportion. To accommodate the vertical proportions trend of the data set, four different training images are simulated. The grain size is simulated alongside the lithological codes and used as an auxiliary variable in the direct sampling implementation of MPS. In this way, one can obtain conditional MPS simulations that preserve the quality and the realism of the training images simulated with the process-imitating method. The main outcome of this study is the possibility of obtaining MPS simulations that respect the statistical properties observed in the real data set and honor the observed conditioning data, while preserving the complex heterogeneity generated by the process-imitating method. In addition, it is demonstrated that an equilibrium of good fit among all the statistical properties of the data set should be considered when selecting a suitable set of parameters for the process-imitating simulations.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><doi>10.1007/s11004-013-9505-y</doi><tpages>20</tpages></addata></record>
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subjects	Algorithms Aquifers Chemistry and Earth Sciences Computer based modeling Computer Science Computer simulation Earth and Environmental Science Earth Sciences Geology Geostatistics Geotechnical Engineering & Applied Earth Sciences Groundwater management Heterogeneity Hydrogeology Mathematical models Parametrization Physics Rivers Simulation Special Issue Statistics for Engineering Training
title	Training Images from Process-Imitating Methods: An Application to the Lower Namoi Aquifer, Murray-Darling Basin, Australia
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