Error control and loss functions for the deep learning inversion of borehole resistivity measurements

Mostafa Shahriari, David Pardo, Jon A. Rivera*, Carlos Torres-Verdín, Artzai Picon, Javier Del Ser, Sebastian Ossandón, Victor M. Calo

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

31 Citations (Scopus)

Abstract

Deep learning (DL) is a numerical method that approximates functions. Recently, its use has become attractive for the simulation and inversion of multiple problems in computational mechanics, including the inversion of borehole logging measurements for oil and gas applications. In this context, DL methods exhibit two key attractive features: (a) once trained, they enable to solve an inverse problem in a fraction of a second, which is convenient for borehole geosteering operations as well as in other real-time inversion applications. (b) DL methods exhibit a superior capability for approximating highly complex functions across different areas of knowledge. Nevertheless, as it occurs with most numerical methods, DL also relies on expert design decisions that are problem specific to achieve reliable and robust results. Herein, we investigate two key aspects of deep neural networks (DNNs) when applied to the inversion of borehole resistivity measurements: error control and adequate selection of the loss function. As we illustrate via theoretical considerations and extensive numerical experiments, these interrelated aspects are critical to recover accurate inversion results.

Original languageEnglish
Pages (from-to)1629-1657
Number of pages29
JournalInternational Journal for Numerical Methods in Engineering
Volume122
Issue number6
DOIs
Publication statusPublished - 30 Mar 2021

Funding

European Regional Development Fund, EFA362/19; Eusko Jaurlaritza, BERC 2018‐2021; KK‐2019‐00068; KK‐2019‐00085; H2020 Marie Skłodowska‐Curie Actions, 777778; Ministerio de Ciencia e Innovación, SEV‐2017‐0718; PID2019‐108111RB‐I00; Ministerio de Economía y Competitividad, MTM2016‐76329‐R Funding information The research reported in this article has been funded by the European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska‐Curie grant agreement No 777778 (MATHROCKS), the European POCTEFA 2014‐2020 Project PIXIL (EFA362/19) by the European Regional Development Fund (ERDF) through the Interreg V‐A Spain‐France‐Andorra programme, the Austrian Ministry for Transport, Innovation and Technology (BMVIT), the Federal Ministry for Digital and Economic Affairs (BMDW), the Province of Upper Austria in the frame of the COMET ‐ Competence Centers for Excellent Technologies Program managed by Austrian Research Promotion Agency FFG, the COMET Module S3AI, the Project of the Spanish Ministry of Economy and Competitiveness with reference MTM2016‐76329‐R (AEI/FEDER, EU), the BCAM “Severo Ochoa” accreditation of excellence (SEV‐2017‐0718), and the Basque Government through the BERC 2018‐2021 program, the two Elkartek projects ArgIA (KK‐2019‐00068) and MATHEO (KK‐2019‐00085), the Consolidated Research Group MATHMODE (IT1294‐19) given by the Department of Education, The University of Texas at Austin Research Consortium on Formation Evaluation, jointly sponsored by Anadarko, Aramco, Baker Hughes, BHP, BP, Chevron, China Oilfield Services Limited, CNOOC International, ConocoPhillips, DEA, Eni, Equinor ASA, ExxonMobil, Halliburton, INPEX, Lundin Norway, Occidental, Oil Search, Petrobras, Repsol, Schlumberger, Shell, Southwestern, Total, Wintershall Dea, and Woodside Petroleum Limited. Carlos Torres‐Verdín is grateful for the financial support provided by the Brian James Jennings Memorial Endowed Chair in Petroleum and Geosystems Engineering. This publication acknowledges the financial support of the CSIRO Professorial Chair in Computational Geoscience at Curtin University and the Deep Earth Imaging Enterprise Future Science Platforms of the Commonwealth Scientific Industrial Research Organisation, CSIRO, of Australia. Additionally, at Curtin University, The Institute for Geoscience Research (TIGeR) and by the Curtin Institute for Computation, kindly provide continuing support. information European Regional Development Fund, EFA362/19; Eusko Jaurlaritza, BERC 2018-2021; KK-2019-00068; KK-2019-00085; H2020 Marie Sk?odowska-Curie Actions, 777778; Ministerio de Ciencia e Innovaci?n, SEV-2017-0718; PID2019-108111RB-I00; Ministerio de Econom?a y Competitividad, MTM2016-76329-RThe research reported in this article has been funded by the European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 777778 (MATHROCKS), the European POCTEFA 2014-2020 Project PIXIL (EFA362/19) by the European Regional Development Fund (ERDF) through the Interreg V-A Spain-France-Andorra programme, the Austrian Ministry for Transport, Innovation and Technology (BMVIT), the Federal Ministry for Digital and Economic Affairs (BMDW), the Province of Upper Austria in the frame of the COMET - Competence Centers for Excellent Technologies Program managed by Austrian Research Promotion Agency FFG, the COMET Module S3AI, the Project of the Spanish Ministry of Economy and Competitiveness with reference MTM2016-76329-R (AEI/FEDER, EU), the BCAM ?Severo Ochoa? accreditation of excellence (SEV-2017-0718), and the Basque Government through the BERC 2018-2021 program, the two Elkartek projects ArgIA (KK-2019-00068) and MATHEO (KK-2019-00085), the Consolidated Research Group MATHMODE (IT1294-19) given by the Department of Education, The University of Texas at Austin Research Consortium on Formation Evaluation, jointly sponsored by Anadarko, Aramco, Baker Hughes, BHP, BP, Chevron, China Oilfield Services Limited, CNOOC International, ConocoPhillips, DEA, Eni, Equinor ASA, ExxonMobil, Halliburton, INPEX, Lundin Norway, Occidental, Oil Search, Petrobras, Repsol, Schlumberger, Shell, Southwestern, Total, Wintershall Dea, and Woodside Petroleum Limited. Carlos Torres-Verd?n is grateful for the financial support provided by the Brian James Jennings Memorial Endowed Chair in Petroleum and Geosystems Engineering. This publication acknowledges the financial support of the CSIRO Professorial Chair in Computational Geoscience at Curtin University and the Deep Earth Imaging Enterprise Future Science Platforms of the Commonwealth Scientific Industrial Research Organisation, CSIRO, of Australia. Additionally, at Curtin University, The Institute for Geoscience Research (TIGeR) and by the Curtin Institute for Computation, kindly provide continuing support.

FundersFunder number
AEI/FEDER
Austrian Research Promotion Agency FFG
BERCIT1294‐19
Curtin Institute for Computation
Deep Earth Imaging Enterprise Future Science Platforms of the Commonwealth Scientific Industrial Research Organisation
Department of Education, The University of Texas at Austin
H2020 Marie Sk?odowska
Halliburton
INPEX
Lundin Norway
Ministerio de Ciencia e Innovaci?n
Spanish Ministry of Economy and Competitiveness
Woodside Petroleum Limited
ConocoPhillips
Horizon 2020 Framework Programme
H2020 Marie Skłodowska-Curie Actions777778
Lundin Energy Norway
European CommissionSEV‐2017‐0718
Commonwealth Scientific and Industrial Research Organisation
Curtin University of Technology
Eusko Jaurlaritza
Ministerio de Economía y CompetitividadMTM2016-76329-R
Ministerio de Ciencia e InnovaciónPID2019‐108111RB‐I00
Österreichische Forschungsförderungsgesellschaft
Bundesministerium für Verkehr, Innovation und Technologie
Horizon 2020
Department of Environmental Affairs
European Regional Development FundEFA362/19, KK‐2019‐00068
Agencia Estatal de Investigación
Bundesministerium für Digitalisierung und Wirtschaftsstandort
ExxonMobil Foundation
Institute for Geoscience Research

    Keywords

    • deep learning
    • deep neural networks
    • error estimation
    • geophysical applications
    • real-time inversion

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