Geologic Interpretation Software

Geological mapping software displaying a screenshot of a structure map generated for an 8500ft deep gas & Oil reservoir in the Earth field, Vermilion Parish, Erath, Louisiana. The left-to-right gap, near the top of the contour map indicates a Fault line. This fault line is between the blue/green contour lines and the purple/red/yellow contour lines. The thin red circular contour line in the middle of the map indicates the top of the oil reservoir. Because gas floats above oil, the thin red contour line marks the gas/oil contact zone.
  1. Kingdom® software provides geoscientists and asset teams the functionality needed for all aspects of their portfolio management from prospect to production, basic and advanced interpretation to microseismic analysis and geosteering resulting in faster interpretation and modeling sharing of complex data and more confident decision making.
  2. Geologic modelling, geological modelling or geomodelling is the applied science of creating computerized representations of portions of the Earth's crust based on geophysical and geological observations made on and below the Earth surface. A geomodel is the numerical equivalent of a three-dimensional geological map complemented by a description of physical quantities in the domain of.

Geologic modelling,geological modelling or geomodelling is the applied science of creating computerized representations of portions of the Earth's crust based on geophysical and geological observations made on and below the Earth surface. A geomodel is the numerical equivalent of a three-dimensional geological map complemented by a description of physical quantities in the domain of interest.[1]Geomodelling is related to the concept of Shared Earth Model;[2] which is a multidisciplinary, interoperable and updatable knowledge base about the subsurface.

This is a list of free and open-source software for geological data handling and interpretation. The list is split into broad categories, depending on the intended use of the software and its scope of functionality. Notice that 'free and open-source' requires that the source code is available. Geologic Interpretation From traditional marker picking to advanced geology. Paradigm ® geological interpretation solutions enable the traditional geologist to do in a day what used to take weeks – well correlation, facies log calculation, cross-section creation and geological restoration. But more than that – with our geological interpretation solutions, any geologist who chooses to is.

Geomodelling is commonly used for managing natural resources, identifying natural hazards, and quantifying geological processes, with main applications to oil and gas fields, groundwater aquifers and ore deposits. For example, in the oil and gas industry, realistic geologic models are required as input to reservoir simulator programs, which predict the behavior of the rocks under various hydrocarbon recovery scenarios. A reservoir can only be developed and produced once; therefore, making a mistake by selecting a site with poor conditions for development is tragic and wasteful. Using geological models and reservoir simulation allows reservoir engineers to identify which recovery options offer the safest and most economic, efficient, and effective development plan for a particular reservoir.

Geologic modelling is a relatively recent subdiscipline of geology which integrates structural geology, sedimentology, stratigraphy, paleoclimatology, and diagenesis;

In 2-dimensions (2D), a geologic formation or unit is represented by a polygon, which can be bounded by faults, unconformities or by its lateral extent, or crop. In geological models a geological unit is bounded by 3-dimensional (3D) triangulated or gridded surfaces. The equivalent to the mapped polygon is the fully enclosed geological unit, using a triangulated mesh. For the purpose of property or fluid modelling these volumes can be separated further into an array of cells, often referred to as voxels (volumetric elements). These 3D grids are the equivalent to 2D grids used to express properties of single surfaces.

Geomodelling generally involves the following steps:

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  1. Preliminary analysis of geological context of the domain of study.
  2. Interpretation of available data and observations as point sets or polygonal lines (e.g. 'fault sticks' corresponding to faults on a vertical seismic section).
  3. Construction of a structural model describing the main rock boundaries (horizons, unconformities, intrusions, faults)[3]
  4. Definition of a three-dimensional mesh honoring the structural model to support volumetric representation of heterogeneity (see Geostatistics) and solving the Partial Differential Equations which govern physical processes in the subsurface (e.g. seismic wave propagation, fluid transport in porous media).
  • 1Geologic modelling components

Geologic modelling components[edit]

Structural framework[edit]

Incorporating the spatial positions of the major formation boundaries, including the effects of faulting, folding, and erosion (unconformities). The major stratigraphic divisions are further subdivided into layers of cells with differing geometries with relation to the bounding surfaces (parallel to top, parallel to base, proportional). Maximum cell dimensions are dictated by the minimum sizes of the features to be resolved (everyday example: On a digital map of a city, the location of a city park might be adequately resolved by one big green pixel, but to define the locations of the basketball court, the baseball field, and the pool, much smaller pixels – higher resolution – need to be used).

Rock type[edit]

Each cell in the model is assigned a rock type. In a coastal clastic environment, these might be beach sand, high water energy marine upper shoreface sand, intermediate water energy marine lower shoreface sand, and deeper low energy marine silt and shale. The distribution of these rock types within the model is controlled by several methods, including map boundary polygons, rock type probability maps, or statistically emplaced based on sufficiently closely spaced well data.

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Reservoir quality[edit]

Geological Interpretation Software

Reservoir quality parameters almost always include porosity and permeability, but may include measures of clay content, cementation factors, and other factors that affect the storage and deliverability of fluids contained in the pores of those rocks. Geostatistical techniques are most often used to populate the cells with porosity and permeability values that are appropriate for the rock type of each cell.

Fluid saturation[edit]

A 3D finite difference grid used in MODFLOW for simulating groundwater flow in an aquifer.

Most rock is completely saturated with groundwater. Sometimes, under the right conditions, some of the pore space in the rock is occupied by other liquids or gases. In the energy industry, oil and natural gas are the fluids most commonly being modelled. The preferred methods for calculating hydrocarbon saturations in a geologic model incorporate an estimate of pore throat size, the densities of the fluids, and the height of the cell above the water contact, since these factors exert the strongest influence on capillary action, which ultimately controls fluid saturations.

Geostatistics[edit]

An important part of geologic modelling is related to geostatistics. In order to represent the observed data, oftennot on regular grids, we have to use certain interpolation techniques. The most widely used technique is krigingwhich uses the spatial correlation among data and intends to construct the interpolation via semi-variograms. To reproduce more realistic spatial variability and help assess spatial uncertainty between data, geostatistical simulation based on variograms, training images, or parametric geological objects is often used.

Mineral Deposits[edit]

Geologists involved in mining and mineral exploration use geologic modelling to determine the geometry and placement of mineral deposits in the subsurface of the earth. Geologic models help define the volume and concentration of minerals, to which economic constraints are applied to determine the economic value of the mineralization. Mineral deposits that are deemed to be economic may be developed into a mine.

Technology[edit]

Geomodelling and CAD share a lot of common technologies. Software is usually implemented using object-oriented programming technologies in C++, Java or C# on one or multiple computer platforms. The graphical user interface generally consists of one or several 3D and 2D graphics windows to visualize spatial data, interpretations and modelling output. Such visualization is generally achieved by exploiting graphics hardware. User interaction is mostly performed through mouse and keyboard, although 3D pointing devices and immersive environments may be used in some specific cases. GIS (Geographic Information System) is also a widely used tool to manipulate geological data.

Geometric objects are represented with parametric curves and surfaces or discrete models such as polygonal meshes.[3][4]

Gravity Highs

Research in Geomodelling[edit]

Problems pertaining to Geomodelling cover:[5][6]

Geological Interpretation Software

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  • Defining an appropriate Ontology to describe geological objects at various scales of interest,
  • Integrating diverse types of observations into 3D geomodels: geological mapping data, borehole data and interpretations, seismic images and interpretations, potential field data, well test data, etc.,
  • Better accounting for geological processes during model building,
  • Characterizing uncertainty about the geomodels to help assess risk. Therefore, Geomodelling has a close connection to Geostatistics and Inverse problem theory,
  • Applying of the recent developed Multiple Point Geostatistical Simulations (MPS) for integrating different data sources,[7]
  • Automated geometry optimization and topology conservation[8]

History[edit]

In the 70's, geomodelling mainly consisted of automatic 2D cartographic techniques such as contouring, implemented as FORTRAN routines communicating directly with plotting hardware. The advent of workstations with 3D graphics capabilities during the 80's gave birth to a new generation of geomodelling software with graphical user interface which became mature during the 90's.[9][10][11]

Since its inception, geomodelling has been mainly motivated and supported by oil and gas industry.

Geologic modelling software[edit]

Software developers have built several packages for geologic modelling purposes. Such software can display, edit, digitise and automatically calculate the parameters required by engineers, geologists and surveyors. Current software is mainly developed and commercialized by oil and gas or mining industry software vendors:

Geologic modelling and visualisation
  • Dassault SystèmesGEOVIA provides Surpac, GEMS and Minex for geologic modeling
  • Seequent provides Leapfrog 3D geological modeling & Geosoft GM-SYS and VOXI 3D modelling software.
  • Maptek provides Vulcan, 3D modular software visualisation for geological modelling and mine planning
  • Datamine Software provides Studio EM and Studio RM for geological modelling
  • BGS Groundhog Desktop free-to-use software developed by the GeoAnalytics and Modelling directorate of British Geological Survey.
Groundwater modelling

Moreover, industry Consortia or companies are specifically working at improving standardization and interoperability of earth science databases and geomodelling software:

Geologic Interpretation Software
  • Standardization: GeoSciML by the Commission for the Management and Application of Geoscience Information, of the International Union of Geological Sciences.
  • Standardization: RESQML(tm) by Energistics
  • Interoperability: OpenSpirit, by TIBCO(r)

See also[edit]

References[edit]

  • Bolduc, A.M., Riverin, M-N., Lefebvre, R., Fallara, F. et Paradis, S.J., 2006. Eskers: À la recherche de l'or bleu. La Science au Québec : http://www.sciencepresse.qc.ca/archives/quebec/capque0606f.html
  • Faure, Stéphane, Godey, Stéphanie, Fallara, Francine and Trépanier, Sylvain. (2011). Seismic Architecture of the Archean North American Mantle and Its Relationship to Diamondiferous Kimberlite Fields. Economic Geology, March–April 2011, v. 106, p. 223–240. http://econgeol.geoscienceworld.org/content/106/2/223.abstract
  • Fallara, Francine, Legault, Marc and Rabeau, Olivier (2006). 3-D Integrated Geological Modeling in the Abitibi Subprovince (Québec, Canada): Techniques and Applications. Exploration and Mining Geology, Vol. 15, Nos. 1–2, pp. 27–41. http://web.cim.org/geosoc/docs/pdf/EMG15_3_Fallara_etal.pdf
  • Berg, R.C., Mathers, S.J., Kessler, H., and Keefer, D. A., 2011. Synopsis of Current Three-dimensional Geological Mapping and Modeling in Geological Survey Organization, Champaign, Illinois: Illinois State Geological Survey, Circular 578. https://web.archive.org/web/20111009122101/http://library.isgs.uiuc.edu/Pubs/pdfs/circulars/c578.pdf
  • Turner, A. K.; Gable, C. (2007). 'A review of geological modelling. In: Three-dimensional geologic mapping for groundwater applications, Workshop extended abstracts,'(PDF). Denver, Colorado. Archived from the original(PDF) on 2008-11-21.
  • Kessler, H., Mathers, S., Napier, B., Terrington, R. & Sobisch, H.-G (2007). 'The present and future construction and delivery of 3D geological models at the British Geological Survey'.CS1 maint: multiple names: authors list (link) (GSA Denver Annual Meeting. Poster)
  • Wycisk,P., Gossel W., Schlesier, D. & Neumann, C (2007). 'Integrated 3D modelling of subsurface geology and hydrogeology for urban groundwater management'(PDF). International Symposium on New Directions in Urban Water Management. Archived from the original(PDF) on 2008-12-17.CS1 maint: multiple names: authors list (link)
  • Kessler, H., Mathers, S., Lelliott, M., Hughes, A. & MacDonald, D. (2007). 'Rigorous 3D geological models as the basis for groundwater modelling. In: Three-dimensional geologic mapping for groundwater applications, Workshop extended abstracts,'(PDF). Denver, Colorado. Archived from the original(PDF) on 2008-12-03.CS1 maint: multiple names: authors list (link)
  • Merritt, J.E., Monaghan, A., Entwisle, D., Hughes, A., Campbell, D. & Browne, M. (August 2007). '3D attributed models for addressing environmental and engineering geoscience problems in areas of urban regeneration – a case study in Glasgow, UK. In: First Break, Special Topic Environmental and Engineering Geoscience'(PDF). pp. Volume 25, pp 79–84.CS1 maint: multiple names: authors list (link)[permanent dead link]
  • Kevin B. Sprague & Eric A. de Kemp. (2005) Interpretive Tools for 3-D Structural Geological Modelling Part II: Surface Design from Sparse Spatial Data http://portal.acm.org/citation.cfm?id=1046957.1046969&coll=&dl=ACM
  • de Kemp, E.A. (2007). 3-D geological modelling supporting mineral exploration. In: Goodfellow, W.D., ed., Mineral Deposits of Canada: A Synthesis of Major Deposit Types, District Metallogeny, the Evolution of Geological Provinces, and Exploration Methods: Geological Association of Canada, Mineral Deposits Division, Special Publication 5, p. 1051–1061. https://web.archive.org/web/20081217170553/http://gsc.nrcan.gc.ca/mindep/method/3d/pdf/dekemp_3dgis.pdf

Footnotes[edit]

  1. ^Mallet, J. L. (2008). Numerical Earth Models. European Association of Geoscientists and Engineers (EAGE Publications bv). ISBN978-90-73781-63-4. Archived from the original on 2016-03-04. Retrieved 2013-08-20.
  2. ^Fanchi, John R. (August 2002). Shared Earth Modeling : Methodologies for Integrated Reservoir Simulations. Gulf Professional Publishing (Elsevier imprint). pp. xi–306. ISBN978-0-7506-7522-2.
  3. ^ abCaumon, G., Collon-Drouaillet, P., Le Carlier de Veslud, C., Sausse, J. and Viseur, S. (2009), Surface-based 3D modeling of geological structures, Mathematical Geosciences, 41(9):927–945
  4. ^Mallet, J.-L., Geomodeling, Applied Geostatistics Series. Oxford University Press. ISBN978-0-19-514460-4
  5. ^Caumon, G., Towards stochastic time-varying geological modeling (2010), Mathematical Geosciences, 42(5):(555-569)
  6. ^Perrin, M., Zhu, B., Rainaud, J.F. and Schneider, S. (2005), Knowledge-driven applications for geological modeling, 'Journal of Petroleum Science and Engineering', 47(1–2):89–104
  7. ^Tahmasebi, P., Hezarkhani, A., Sahimi, M., 2012, Multiple-point geostatistical modeling based on the cross-correlation functions, Computational Geosciences, 16(3):779-79742
  8. ^M.R. Alvers, H.J. Götze, B. Lahmeyer, C. Plonka and S. Schmidt, 2013, Advances in 3D Potential Field Modeling EarthDoc, 75th EAGE Conference & Exhibition incorporating SPE EUROPEC 2013
  9. ^Dynamic Graphics HistoryArchived 2011-07-25 at the Wayback Machine
  10. ^Origin of the Gocad software
  11. ^J. L. Mallet, P. Jacquemin, and N. Cheimanoff (1989). GOCAD project: Geometric modeling of complex geological surfaces, SEG Expanded Abstracts 8, 126, doi:10.1190/1.1889515

External links[edit]

Retrieved from 'https://en.wikipedia.org/w/index.php?title=Geologic_modelling&oldid=919504526'

This is a list of free and open-source software for geological data handling and interpretation. The list is split into broad categories, depending on the intended use of the software and its scope of functionality.

Notice that 'free and open-source' requires that the source code is available. Simple being 'free of charge' is not sufficient—see gratis versus libre.

Well logging & Borehole visualisation[edit]

NameDescriptionOriginatorLicensePlatformsLanguageNotes
SGS-Geobase [1]Drilling data logger that can interface with SGS GenesisSGS Canada Inc.GPLWindows & Microsoft AccessMicrosoft Access VBAMicrosoft Access is not necessary, the free runtime is sufficient. Simple graphical interface, Integrity reinforcement, Reporting tools, Satellite Database, Database Validation, Assays QA/QC management with graphics.
LOGitEASYCloud-based field logging software, boring log software, geologic cross section softwarehttps://logiteasy.comFree/

Pay-As-You-Go/

Subscription

Windows, Mac OS, iOS, AndroidPHP, JavaBased on USCS Soil Classification Standard, allows generating instant PDF boring logs and geologic cross sections from the data logged using the LOGitEASY eForm

Geosciences software platforms[edit]

NameDescriptionOriginatorLicensePlatformsLanguageNotes
GeoTriple for Oil&Gas ExplorationGeo-sciences Software platform (data management, display and process)Geoforge projectLGPLCross-platformJavaInterfaces with WorldWind and JFreeChart

Geostatistics[edit]

NameDescriptionOriginatorLicensePlatformsLanguageNotes
Gstat[3]Geostatistical modeling and simulationUtrecht UniversityGPLCross-platformC/C++Interfaces with GRASS
gslib[4]Geostatistical modeling and simulationStanford UniversityMITFortran 77
PyGSLIB[5]Python module for geostatistical modeling, designed for mineral resource estimationOpengeostat ConsultingMIT/GPLWindows, Linux and OSXFortran 95, Cython and PythonIt has functions for drillhole calculations, block modeling, wireframing and geostatistics with modified gslib code linked into python

Forward modeling[edit]

Youtube Geological Interpretation Software

NameDescriptionOriginatorLicensePlatformsLanguageNotes
Virtual Geoscience Workbench[6]Finite-discrete element modelerJiansheng Xiang and othersLGPLWindowsC#, C++

Geomodeling[edit]

NameDescriptionOriginatorLicensePlatformsLanguageNotes
GeoSyntax[7]Reservoir modelingCSIRO Australia - June HillCSIRO 'MIT/BSD' (academic)Microsoft WindowsJava
GeoBlock[8]Reservoir modelingPavel VassilievMPLMicrosoft WindowsEmbarcadero DelphiExact terms not clear
GeoTrace[9]Tracer modelingMuhammed CelikMicrosoft WindowsVisual BasicExact terms not clear
Albion[10]3D model reconstruction and visualisation from boreholes based on QGIS GIS PlatformOslandia[11] and ArevaGPLv2 or laterMicrosoft Windows and LinuxPython

Visualization, interpretation & analysis packages[edit]

NameDescriptionOriginatorLicensePlatformsLanguageNotes
Dapple[12]Virtual globe for geoscientistsGeosoft Inc.MITWindowsOriginated in NASA World Wind
Generic Mapping Tools[13]Map generation and analysisLamont-Doherty and University of HawaiiGPLCross-platformCImplemented in OpendTect
GPlates[14]Interactive visualization of plate tectonicsUniversity of Sydney, Caltech, NGUGPLCross-platformC++, PythonImplements GPML
OpenStereo[15]Geoscience plotting toolCarlos Grohmann, University of São PauloGPLCross-platformPythonDepends on NumPy and Matplotlib
SvgNet[16]Stereographic and Spherical ProjectionsArijit Laik[17]public domainWebAppJavaScriptDepends on JavaScript, HTML5 and SVG support in browser
OpendTect[18]Geoscience interpretation and visualizationdGB Earth SciencesGPL or customCross-platformC++Interfaces with GMT
ParaViewGeo[19]Geoscience extension of ParaView Includes readers and filtersKitwareParaView, Objectivity Originally MIRARCOBSDCross-platformC++, PythonAdds specific readers, stereo toolbar, slideshow capability and mining and geology oriented filters to Paraview
PuffinPlot[20]Paleomagnetic data visualization and analysisPontus LurcockGPL v3Cross-platformJavaDesktop GUI and Jython scripting interface.

Geographic information systems (GIS)[edit]

This important class of tools is already listed in the article List of GIS software.

Not true free and open-source projects[edit]

The following projects have unknown licensing, licenses or other conditions which place some restriction on use or redistribution, or which depend on non-open-source software like MATLAB or XVT (and therefore do not meet the Open Source Definition from the Open Source Initiative).

NameDescriptionOriginatorLicensePlatformsLanguageNotes
VGeST[21]Discontinuum modelingICL and QMULNot obviousMicrosoft WindowsC#?Previously known as VGW
Javageo[22]Multidisciplinary interpretation toolGoen GhinNot clearCross-platformJava (software platform)
Noddy[23]3D geological and geophysical modelingTectask, IUGSCustom permissive licenseMicrosoft WindowsC++Uses proprietary XVT libraries; requires (free) registration
RGeostats[24]Geostatistical R PackageDidier Renard (Mines-Paristech)LICENSECross-platformR (programming language)Free R Package
Flumy[25]Forward reservoir models for meandering channelized systemsARMINES - Mines-ParistechLICENSECross-platformC++Free demonstration version
BasinVis[26]Basin visualization of sedimentary fill and subsidenceEun Young Lee, Johannes NovotnyLICENSECross-platformMatlab
Geomodelr[27]Geological modelling from cross sectionsGeomodelr, Inc.SaaS - AGPLCross-platformPythonAllows creation of public geological models in its web platform for free and query the model with an Open Source Python Package
BGS Groundhog Desktop[28]Geological modelling from cross sectionsBritish Geological SurveyOGL - Open Government LicenceMS WindowsJavaFree to use software to digitize geological cross-sections, and display and edit borehole logs

References[edit]

  1. ^http://www.geostat.com/genesis/en/download.php
  2. ^http://www.geoforge.org/prt/product/gtr4oxp/gtr4oxp_about.html
  3. ^http://gstat.org
  4. ^http://gslib.com
  5. ^'opengeostat/pygslib'. GitHub. Retrieved 2016-09-09.
  6. ^http://sourceforge.net/projects/vgw/
  7. ^https://data.csiro.au/dap/landingpage?pid=csiro:10810
  8. ^http://geoblock.sourceforge.net/
  9. ^http://www.geoseis.tr.gg/
  10. ^https://github.com/Oslandia/albion
  11. ^http://oslandia.com
  12. ^http://dapple.geosoft.comArchived 2006-08-13 at the Wayback Machine
  13. ^http://gmt.soest.hawaii.edu
  14. ^http://www.gplates.org
  15. ^http://www.igc.usp.br/index.php?id=openstereo
  16. ^https://svgnet.github.io
  17. ^https://github.com/arijitlaik
  18. ^http://opendtect.org
  19. ^http://paraviewgeo.objectivity.ca
  20. ^Lurcock, P. C. and G. S. Wilson (2012), PuffinPlot: A versatile, user-friendly program for paleomagnetic analysis, Geochemistry, Geophysics, Geosystems, 13, Q06Z45, doi:10.1029/2012GC004098
  21. ^http://vgest.net
  22. ^http://javageo.com
  23. ^http://www.tectonique.net/tectask/index.php?option=com_content&view=article&id=23
  24. ^http://cg.ensmp.fr/rgeostats
  25. ^http://cg.ensmp.fr/flumy
  26. ^http://geologist-lee.com/basinvis.html
  27. ^https://geomodelr.com
  28. ^https://www.bgs.ac.uk/research/environmentalModelling/groundhogDesktop.html
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