Multiple point statistical simulation using uncertain (soft) conditional data

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Multiple point statistical simulation using uncertain (soft) conditional data. / Hansen, Thomas Mejer; Vu, Le Thanh; Mosegaard, Klaus; Cordua, Knud Skou.

I: Computers & Geosciences, Bind 114, 01.05.2018, s. 1-10.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Hansen, TM, Vu, LT, Mosegaard, K & Cordua, KS 2018, 'Multiple point statistical simulation using uncertain (soft) conditional data', Computers & Geosciences, bind 114, s. 1-10. https://doi.org/10.1016/j.cageo.2018.01.017

APA

Hansen, T. M., Vu, L. T., Mosegaard, K., & Cordua, K. S. (2018). Multiple point statistical simulation using uncertain (soft) conditional data. Computers & Geosciences, 114, 1-10. https://doi.org/10.1016/j.cageo.2018.01.017

Vancouver

Hansen TM, Vu LT, Mosegaard K, Cordua KS. Multiple point statistical simulation using uncertain (soft) conditional data. Computers & Geosciences. 2018 maj 1;114:1-10. https://doi.org/10.1016/j.cageo.2018.01.017

Author

Hansen, Thomas Mejer ; Vu, Le Thanh ; Mosegaard, Klaus ; Cordua, Knud Skou. / Multiple point statistical simulation using uncertain (soft) conditional data. I: Computers & Geosciences. 2018 ; Bind 114. s. 1-10.

Bibtex

@article{f6a6fd9d253846fdaa82799053b93860,
title = "Multiple point statistical simulation using uncertain (soft) conditional data",
abstract = "Geostatistical simulation methods have been used to quantify spatial variability of reservoir models since the 80s. In the last two decades, state of the art simulation methods have changed from being based on covariance-based 2-point statistics to multiple-point statistics (MPS), that allow simulation of more realistic Earth-structures. In addition, increasing amounts of geo-information (geophysical, geological, etc.) from multiple sources are being collected. This pose the problem of integration of these different sources of information, such that decisions related to reservoir models can be taken on an as informed base as possible. In principle, though difficult in practice, this can be achieved using computationally expensive Monte Carlo methods. Here we investigate the use of sequential simulation based MPS simulation methods conditional to uncertain (soft) data, as a computational efficient alternative. First, it is demonstrated that current implementations of sequential simulation based on MPS (e.g. SNESIM, ENESIM and Direct Sampling) do not account properly for uncertain conditional information, due to a combination of using only co-located information, and a random simulation path. Then, we suggest two approaches that better account for the available uncertain information. The first make use of a preferential simulation path, where more informed model parameters are visited preferentially to less informed ones. The second approach involves using non co-located uncertain information. For different types of available data, these approaches are demonstrated to produce simulation results similar to those obtained by the general Monte Carlo based approach. These methods allow MPS simulation to condition properly to uncertain (soft) data, and hence provides a computationally attractive approach for integration of information about a reservoir model.",
keywords = "Data integration, Multiple point statstics, Uncertain data",
author = "Hansen, {Thomas Mejer} and Vu, {Le Thanh} and Klaus Mosegaard and Cordua, {Knud Skou}",
year = "2018",
month = may,
day = "1",
doi = "10.1016/j.cageo.2018.01.017",
language = "English",
volume = "114",
pages = "1--10",
journal = "Computers & Geosciences",
issn = "0098-3004",
publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - Multiple point statistical simulation using uncertain (soft) conditional data

AU - Hansen, Thomas Mejer

AU - Vu, Le Thanh

AU - Mosegaard, Klaus

AU - Cordua, Knud Skou

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Geostatistical simulation methods have been used to quantify spatial variability of reservoir models since the 80s. In the last two decades, state of the art simulation methods have changed from being based on covariance-based 2-point statistics to multiple-point statistics (MPS), that allow simulation of more realistic Earth-structures. In addition, increasing amounts of geo-information (geophysical, geological, etc.) from multiple sources are being collected. This pose the problem of integration of these different sources of information, such that decisions related to reservoir models can be taken on an as informed base as possible. In principle, though difficult in practice, this can be achieved using computationally expensive Monte Carlo methods. Here we investigate the use of sequential simulation based MPS simulation methods conditional to uncertain (soft) data, as a computational efficient alternative. First, it is demonstrated that current implementations of sequential simulation based on MPS (e.g. SNESIM, ENESIM and Direct Sampling) do not account properly for uncertain conditional information, due to a combination of using only co-located information, and a random simulation path. Then, we suggest two approaches that better account for the available uncertain information. The first make use of a preferential simulation path, where more informed model parameters are visited preferentially to less informed ones. The second approach involves using non co-located uncertain information. For different types of available data, these approaches are demonstrated to produce simulation results similar to those obtained by the general Monte Carlo based approach. These methods allow MPS simulation to condition properly to uncertain (soft) data, and hence provides a computationally attractive approach for integration of information about a reservoir model.

AB - Geostatistical simulation methods have been used to quantify spatial variability of reservoir models since the 80s. In the last two decades, state of the art simulation methods have changed from being based on covariance-based 2-point statistics to multiple-point statistics (MPS), that allow simulation of more realistic Earth-structures. In addition, increasing amounts of geo-information (geophysical, geological, etc.) from multiple sources are being collected. This pose the problem of integration of these different sources of information, such that decisions related to reservoir models can be taken on an as informed base as possible. In principle, though difficult in practice, this can be achieved using computationally expensive Monte Carlo methods. Here we investigate the use of sequential simulation based MPS simulation methods conditional to uncertain (soft) data, as a computational efficient alternative. First, it is demonstrated that current implementations of sequential simulation based on MPS (e.g. SNESIM, ENESIM and Direct Sampling) do not account properly for uncertain conditional information, due to a combination of using only co-located information, and a random simulation path. Then, we suggest two approaches that better account for the available uncertain information. The first make use of a preferential simulation path, where more informed model parameters are visited preferentially to less informed ones. The second approach involves using non co-located uncertain information. For different types of available data, these approaches are demonstrated to produce simulation results similar to those obtained by the general Monte Carlo based approach. These methods allow MPS simulation to condition properly to uncertain (soft) data, and hence provides a computationally attractive approach for integration of information about a reservoir model.

KW - Data integration

KW - Multiple point statstics

KW - Uncertain data

UR - http://www.scopus.com/inward/record.url?scp=85044373267&partnerID=8YFLogxK

U2 - 10.1016/j.cageo.2018.01.017

DO - 10.1016/j.cageo.2018.01.017

M3 - Journal article

VL - 114

SP - 1

EP - 10

JO - Computers & Geosciences

JF - Computers & Geosciences

SN - 0098-3004

ER -

ID: 189150732