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Application of artificial neural networks to downhole fluid analysis

Hegemann, Peter, Dong Chengli, Varotsis Nikolaos, Gaganis Vasileios

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URIhttp://purl.tuc.gr/dl/dias/F074C258-28B0-4A56-B07B-016883288653-
Identifierhttps://doi.org/http://dx.doi.org/10.2118/123423-PA-
Identifierhttps://www.onepetro.org/journal-paper/SPE-123423-PA-
Languageen-
Extent6 pagesen
TitleApplication of artificial neural networks to downhole fluid analysisen
CreatorHegemann, Peteren
CreatorDong Chenglien
CreatorVarotsis Nikolaosen
CreatorΒαροτσης Νικολαοςel
CreatorGaganis Vasileiosen
CreatorΓαγανης Βασιλειοςel
PublisherSociety of Petroleum Engineersen
Content SummaryReservoir characterization and asset management require comprehensive information about formation fluids. Obtaining this information at all stages of the exploration and development cycle is essential for field planning and operation. Traditionally, fluid information has been obtained by capturing samples and then measuring the pressure/volume/temperature (PVT) properties in a laboratory. More recently, downhole fluid analysis (DFA) during formation testing has provided real-time fluid information. However, the extreme conditions of the downhole environment limit the DFA-tool measurements to only a small subset of the fluid properties provided by a laboratory. Nevertheless, these tools are valuable in predicting other PVT properties from the measured data. These predictions can be used in real time to optimize the sampling program, to help evaluate completion decisions, and to understand flow-assurance issues. The petroleum industry has devoted much effort to developing computational methods to model phase behavior. Two approaches are prevalent—simple correlations and equation-of-state (EOS) models. However, in recent years, artificial-neural-network (ANN) technology has been applied successfully to many petroleum-engineering problems, including the prediction of PVT behavior. ANN technology can recognize patterns in data, adjust dynamically to changes, infer general rules from specific cases, and accept a large number of input variables. An ANN architecture can allow for continuous improvement by expanding the training database with new data. In this paper, we present the application of ANN technology to DFA. We demonstrate this with an ANN model that uses the DFA-tool measurements of fluid composition as input and produces predictions of gas/oil ratio (GOR), a key PVT property used in real time to monitor a formation-tester sampling job. The ANN also provides an uncertainty estimation of its outputs as a quality-assurance indicator. We compare ANN results with those from the algorithms used by DFA tools.en
Type of ItemPeer-Reviewed Journal Publicationen
Type of ItemΔημοσίευση σε Περιοδικό με Κριτέςel
Licensehttp://creativecommons.org/licenses/by/4.0/en
Date of Item2015-11-07-
Date of Publication2009-
SubjectArtificial neural networksen
SubjectNets, Neural (Computer science)en
SubjectNetworks, Neural (Computer science)en
SubjectNeural nets (Computer science)en
Subjectneural networks computer scienceen
Subjectartificial neural networksen
Subjectnets neural computer scienceen
Subjectnetworks neural computer scienceen
Subjectneural nets computer scienceen
Bibliographic CitationP. Hegeman, C. Dong, N. Varotsis and V. Gaganis, “Application of artificial neural networks to downhole fluid analysis”, SPE Reservoir Evaluation & Engineering, vol. 12, no. 1, pp. 8-13, 2009. doi: http://dx.doi.org/10.2118/123423-PAen

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