Abstract
A hierarchical sequential Gaussian cosimulation method is applied in this study for modeling the variables with an inequality constraint in the bivariate relationship. An algorithm is improved by embedding an inverse transform sampling technique in the second simulation to reproduce bivariate complexity and accelerate the process of cosimulation. A heterotopic simple cokriging (SCK) is also proposed, which introduces two moving neighborhoods: single and multiple searching strategies in both steps of the hierarchical process. The proposed algorithm is tested over a real case study from an iron deposit where iron and aluminum oxide shows a strong bivariate dependency as well as a sharp inequality constraint. The results showed that the proposed hierarchical cosimulation with a multiple searching strategy provides satisfying results compared to the case when a single searching strategy is employed. Moreover, the proposed algorithm is compared to the conventional hierarchical cosimulation, which does not implement the inverse transform sampling integrated into the second simulation. The proposed methodology successfully reproduces inequality constraint, while conventional hierarchical cosimulation fails in this regard. However, it is demonstrated that the proposed methodology requires further improvement for better reproduction of global statistics (i.e., mean and standard deviation).
Highlights
Multivariate geostatistics is an essential tool for resource modeling in the presence of moderate or strong correlation between coregionalized variables [Goovaerts, 1997, Chilès and Delfiner, 2012, Pyrcz and Deutsch, 2014, Rossi and Deutsch, 2014]
Throughout the paper, the conventional hierarchical sequential Gaussian cosimulation refers to the algorithm with the same searching strategies but without inverse transform sampling integrated into the second simulation
We propose an alternative of this hierarchical cosimulation algorithm for modeling variables with inequality constraint where the acceptance– rejection method is replaced with an inverse transform sampling technique, which accelerates the algorithm
Summary
Multivariate geostatistics is an essential tool for resource modeling in the presence of moderate or strong correlation between coregionalized variables [Goovaerts, 1997, Chilès and Delfiner, 2012, Pyrcz and Deutsch, 2014, Rossi and Deutsch, 2014]. Implementation of geostatistical factorization, namely projection pursuit multivariate transform [Barnett et al, 2014, 2016], flow anamorphosis [van den Boogaart et al, 2017], among others, are designed to deal with complexities These factorization methods have difficulty in reproducing geological inequality constraints present in bivariate relationships. One significant limitation of these factorization algorithms is that they can be applied mostly on isotopic data sets, wherever the sample observations of variables are required to share the exact locations Another impediment of some of these approaches is that the marginal distributions of both cross-correlated variables should be identical
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