Development of two geostatistical programs: Program-1 for estimating categorical variable distribution by multiple-point statistics; Program-2 for optimizing estimates by Program-1 applying genetic algorithm

Ema Aoi, Tsubasa Onishi, Masanori Kurihara

    Research output: Contribution to conferencePaper

    Abstract

    Precisely describing subsurface structures can lead to the discovery of by-passed oil and gas, to reliable development planning, and hence to maximized proved reserves1). Geostatistics has become popular as a key technique for describing the subsurface structures. Among a variety of geostatistical methods, indicator based approaches including indicator kriging (IK) and sequential indicator simulation(SIS) enable the estimation ofdistributions of categorical variables (e.g., facies). In addition to these traditional two-point geostatistical methods, a multiple-point statistics (MPS) approach has been proposed for reconstructing complex patterns of a structure such as curvilinear shapes. In this study, first, weconstructed the geostatistical program (Program-1) capable of estimating the distribution of categorical variables by IK, SIS and MPS. The comparison among the facies distributions estimated by these methods revealed that MPS was superior in reproducing complex facies distributions. Second, wedeveloped the program (Program-2) to modify/tune the facies distribution estimated by Program-1, through the history matching using the genetic algorithm (GA). GA is an adaptive heuristic search algorithm premised on the evolutionary ideas of natural selection and genetics. Weverified that the facies distribution estimated by Program-1 was successfully improved so that it could rigorouslyreproduce the dynamic well performances such as bottomhole pressure and oil/water production rates. The well performances are simulated with every realizationfor the selection of superior realizations by GA, which results in the significant amount of CPU-time. Hence,wefurther improved Program-2 applying a multi-dimensional scaling (MDS) and k-means clustering. MDS can map the distance of the similarity between each realization into a low dimensional space. In accordance with this mapped similarity, eachrealization of facies distribution can be grouped by k-means clustering. In this modified Program-2, the well performances are simulated only for the representative onesfor each group of realizations for the selection of superior realizations, which contributed to the dramatic reduction of CPU-time by Program-2.

    Original languageEnglish
    Publication statusPublished - 2015 Jan 1
    Event21st Formation Evaluation Symposium of Japan 2015 - Chiba, Japan
    Duration: 2015 Oct 132015 Oct 14

    Other

    Other21st Formation Evaluation Symposium of Japan 2015
    CountryJapan
    CityChiba
    Period15/10/1315/10/14

    Fingerprint

    genetic algorithm
    Genetic algorithms
    Statistics
    Program processors
    Oils
    Gases
    kriging
    Planning
    Water
    statistics
    distribution
    programme
    oil
    geostatistics
    heuristics
    natural selection
    simulation
    indicator
    history
    gas

    ASJC Scopus subject areas

    • Energy Engineering and Power Technology
    • Economic Geology
    • Geochemistry and Petrology
    • Geotechnical Engineering and Engineering Geology
    • Geology

    Cite this

    Development of two geostatistical programs : Program-1 for estimating categorical variable distribution by multiple-point statistics; Program-2 for optimizing estimates by Program-1 applying genetic algorithm. / Aoi, Ema; Onishi, Tsubasa; Kurihara, Masanori.

    2015. Paper presented at 21st Formation Evaluation Symposium of Japan 2015, Chiba, Japan.

    Research output: Contribution to conferencePaper

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    abstract = "Precisely describing subsurface structures can lead to the discovery of by-passed oil and gas, to reliable development planning, and hence to maximized proved reserves1). Geostatistics has become popular as a key technique for describing the subsurface structures. Among a variety of geostatistical methods, indicator based approaches including indicator kriging (IK) and sequential indicator simulation(SIS) enable the estimation ofdistributions of categorical variables (e.g., facies). In addition to these traditional two-point geostatistical methods, a multiple-point statistics (MPS) approach has been proposed for reconstructing complex patterns of a structure such as curvilinear shapes. In this study, first, weconstructed the geostatistical program (Program-1) capable of estimating the distribution of categorical variables by IK, SIS and MPS. The comparison among the facies distributions estimated by these methods revealed that MPS was superior in reproducing complex facies distributions. Second, wedeveloped the program (Program-2) to modify/tune the facies distribution estimated by Program-1, through the history matching using the genetic algorithm (GA). GA is an adaptive heuristic search algorithm premised on the evolutionary ideas of natural selection and genetics. Weverified that the facies distribution estimated by Program-1 was successfully improved so that it could rigorouslyreproduce the dynamic well performances such as bottomhole pressure and oil/water production rates. The well performances are simulated with every realizationfor the selection of superior realizations by GA, which results in the significant amount of CPU-time. Hence,wefurther improved Program-2 applying a multi-dimensional scaling (MDS) and k-means clustering. MDS can map the distance of the similarity between each realization into a low dimensional space. In accordance with this mapped similarity, eachrealization of facies distribution can be grouped by k-means clustering. In this modified Program-2, the well performances are simulated only for the representative onesfor each group of realizations for the selection of superior realizations, which contributed to the dramatic reduction of CPU-time by Program-2.",
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