Overview of the Move Tutorials
OVERVIEW OF THE MOVE TUTORIALS This section provides an overview of each Move tutorial and introduces you to the Move user interface (Figure 1-2). The Move suite consists of the Move Core Appli cation - a powerful stand-alone environment that can be used for 2D cross-secti on construction, 3D mod el building, data int egration and analysis. The Core Application also provides the base for specialist structural modules in 2D and 3D Kinematic Modelling, Geomechanical, Fracture and Fault Respons e Modelling, as well as Strain Capture, Fault Analysis and Stress Analysis. Figures 1 and 2 show the location of some the components com monly referred to in the Move tutorials.
Figure 1: Image showing the location of the Model Building, Data & Analysis, Modules and View panels, Quick Tools toolbar and the Display toolbar, which are referred to in throughout the tutorials.
Figure 2: Image showing the location of the Model Browser and Quick Editor.
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Overview of the Move Tutorials
Move can be used to build geometrically valid interpretations based on geological principles. It is designed by geologists for geologists, in order to provide a best practice environment for model building and testing geological interpretations and concepts. The Mov e tutorials use a range of functionality and cover specific structural geological scenarios in a clear, gui ded workflow. It is recommended that new Move users start from Tutorial 1, because as the tuto rials progress, they increase in complexity and tend to assume the basi c principles of Move. In the following table, each tutorial is marked by a Move Cor e Application or module logo. In order to use th e kinematic and advanced modules, an active license to the Move Core Application and the module in question is required.
Tutor ial 1) Working in Move
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2) Loading and Visualizing Seismic Data
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How to open a project and drape an image over a DEM. Interactivity between the four views within Move ( 3D View , Map View, Section View and Google Map View) and some of the display options available within each view. Introduction to object and model organisation, filtering and editing in the Model Browser and Quick Edit or. How to import a SEG-Y file using the SEG-Y Importer. How to optimize the display of a seismic image using a range of options in the Quick Edit or and the Colour Map tool. How to create new sections from the seismic image using the Section and From Objects tools. A generic workflow is also provided for working with a 3D seismic cube.
3) Loading and Visualizing Well Data
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4) Sections From a 3D Model
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5) Integrating Digital Mapping Tools with Move
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How to import well tracks (including horizon tops and dip data) using the Ascii Well Data Importer and to demonstrate how the data should be conditioned prior to import. How to add survey data (logs, dipmeter, tops ) to pre-ex isting well tracks. How to analyse well data by creating a well interpretation section, edit marker positions usin g the Well Marker tool, analyse logs using the Well Log tool, as well as extend well tracks and add side tracks. How to create 2D cross-secti ons from a 3D model using two workflows. Digitize a section trace in the Map View using the Trace tool and collect the surface intersections after section creation. Slice single and multiple sections through a 3D model using the Section tool in the 3D View. How to display multiple sections in one view. How to cache online maps in FieldMove, so that they can be displayed with little to no data connection whilst mapping. How to create MBTiles and GeoTIFF maps, and prepare a Stratigraphy Column in Move. How to import maps and a StratColumn into FieldMove and FieldMove Clino. How to export data from FieldMove and FieldMove Clino. How to use Mov e to display, analyse and project data col lected whilst mapping.
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Overview of the Move Tutorials
Tutor i al 6) Section Construction from Surface Data
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7) Building, Restoring and Validating a Geological Model
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How to model the subsurface structure of Sheep Mountain Anticline (Colorado) based on field data. How to determine the opt imum orientation for section construction using the stereo plot (accessed via the Vertex Attributes ) and project all (or part of) the di p data to the pl ane of section using the To Section tool. How to use the Horizons from Template tool to construct the anticline fold geometry using a template line and template dip data. Three fold construction methods are explored: parallel/similar, kink band and isogon . How to use the Edit , Split, Join a nd Extend tools to modify the data. How to build, restore and validate a geolo gical interpretation of the Rocky Mountains. How to import a DEM, geological map and three cross-secti on images using the GIS Raster Importer. How to load a Stratigraphy database , digitize faults and horizons in 2D, and generate 3D sur faces from line data. How to validate an interpretation by line-length unfolding to horizontal with the 2D Section Analysis tool. How to restore an imbricate thrust sheet using the 2D Move-onFault and 2D Unfolding tools, wh ilst keeping the secti on tidy with the Advanced Tidy and Resample tools.
8) Modifying Sections in 2D and 3D l
9) 3D Model Building Ordinary Kriging
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How to edit an incorrect cross-secti on interpretation using a valid 3D surface and projecting the intersections into the Section View.
How to build a surface from point data (line vertices and well markers) using the Surface tool and the Delaunay Triangulation and Ordinary Kriging algorithms. How to account for surface anisotropy with the Ordinary Kriging algorithm.
10) 3D Model Building - 3D Dip Domain l
How to build a surface and faults from line data using the Horizons from Template tool and 3D Dip Domain (Ribbon) method.
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Overview of the Move Tutorials
Tutor ial 11) 3D Model Conditioning
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How to split and cut fault offsets on a surface by collecting polygon and line data in the Split tool. How to fill holes and Resample a surface with the Grid Sampling algorithm so that the mesh is regular. How to snap a surface to a fault using the Snap tool. How to fix a corrupt surface using the Topology tool.
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How to edit a surface to honour real-time data updates using the Reshape tool. This includes reshaping to a well marker, a line and a picked point.
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14) Attribute Analysis, Creation and Display
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How to use the SCAT (Statistical Curvature Analysis Technique) tool to aid in the structural interpretation of dip data. It goes through the various display, a nalysis, interpretation and editing functions.
How to create, anal yse and display attributes (dip, dip azimuth and thickness) on a surface using the Surface Geometryand Colour Map tools. How to reconstruct an eroded surface using the calculated average thickness, Horizons from Template tool and Surface tool. How surface attributes can be displayed and colour mapped as contours . How to display point cloud attributes using the Quick Edit or. How to interpolate attributes from a point cloud onto a surface using the Vertex Attributes analyser and Kriging algorithm.
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How to restore the effects of thermal subsidence by applying i) a constant beta and ii) a variable beta across section. How to assess t he relationship between the subsidence an d burial history using the 2D Thermal Subsidence and 2D Decompaction tools.
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16) 2D Backstripping (Louisiana Rollover Dataset)
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How to establish the juxtaposition, migration and charge potential associated with the footw all trap in the Louisiana Rollover. How to import an image, digitize the faults and horizons and set up a Rock Properties database fo r use in the 2D Depth Conversion tool. How to restore the section using a combination of the 2D Move-onFault and 2D Decompaction tools and evaluate the charge risk . How to decompact growth strata using the
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Overview of the Move Tutorials
Tutor i al 17) Flexural Slip Restoration
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18) Prograding Delta Restoration
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How to validate an interpretation of the Wheeler Ridge Anticline using the 2D Section Analysis tool. How to use the Fault Geometry tool and Area-Depth calculation to determine the depth to fault detachment. How to restore the Wheeler Ridge Anticline by individually unfolding each three fault blocks using the Flexural Slip algorithm of the 2D Unfolding tool. How to refit the fault blocks together using the Basic Transform tool, identify and correct any space mismatches through a combination of the Edit a nd Split tools. How to forward model the restored section to its present day geometry using the 2D Move-on-Fault tool.
How to block restore a section back to its restored geometry and identify its deposition al geometry. How to use the Basic Transform and 2D Block Restoration tools to restore the fault offsets of a digitized interpretation and associated seismic image. How to digitize a depositional model and forward model the section to presen t day in order to analyse its reser voir potential.
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19) North Sea Block Restoration
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How to validate an interpretation of a faulted oilfield in the North Sea.
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How to import and depth convert a se ismic image using default parameters. Specific help on polygon creation and troubleshooting workarounds. How to restore the fault blocks using the 2D Decompaction, Horizons from Template, 2D Unfolding a nd 2D Block Restoration tools. How to validate the interpretation by refitting the fault blocks together and identifying any space issues.
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How to restore a section containing salt using the 2D Decompaction, 2D Move-on-Fault , and 2D Unfolding tools. How to calculate the average Airy isostatic response during decompaction, by attaching the calculation grid and using the Vertex Attributes analyser to obtain the aver age across the section.
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21) Construct Horizons from Fault
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How to model horizon shape from the underlying fault geometry using the Horizons from Fault tool. Explores how the Simple Shear algorithm and parameters including the shear angle, num ber of beds, bed thickness and heave can be used to model horizon geometry, using a seismic section as a guid e. How to interactively match the modelled horizon geometry to a seismic image, whilst applying a variable heave.
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Overview of the Move Tutorials
Tutor ial
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22) 2D Forward Modelling l
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To explore how the 2D Move-on-Fault algorithms (Simple Shear, Fault Bend Fold, Detachment Fold and Trishear) model deformation on a simple layer section. To forward model structures such as duplex zones, intruding wedges and imbricate thrusts. A case study from the Niger Delta is also used to represent the application to ‘real world’ scenarios.
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23) 3D Forward Modelling
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24) 3D Depth Conversion, Thermal Subsidence and Decompaction
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How to use the trishear algorithm to attempt to restore a faultcontrolled monocline from the Kaibab Uplift in northern Arizona. To see how variables such as constan t and variable slip influence the deformation geometry, the 3D Move-on-Fault tool is used in conjunction with attribute visualization tools such as the Surface Geometry, Colour Map and Contour tools. How to create an d forward model an 3D extensional block model using the 3D Move-on-Fault tool and apply a comb ination of constant heave, variable symmetric and variable asymmetric heave using the simple shear algorithm. How to use the 3D Model Analysis tool to compar e the area of each horizon before and after deformation.
Howto depth convert a 3D model using the Database method. How to restore the thermal subsidence with variable beta values in a 3D model . Howto decompact a 3D model in order to predict the palaeobathymetry. How to model flexural isost asy using the 3D Decompaction tool.
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25) 3D Unfolding and Area Misfit
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Howto unfold a 3D paral lel fold using the flexural slip and simple shear algorithms, and to compare the difference between the restored geometries using the Surface Geometrytool. How to use the 3D Area Misfit tool to unfold, 'jigsaw restore' and quantifyamoun t of gap or overlap between deformed 3D fault blocks.
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26) 3D Move-on-Fault l
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How to use the 3D Move-on-Fault tool to model simple shear deformation on a listric normal fault and fault parallel flow deformation on a flat-ramp-flat fault. How to use the Strain Capture tool to visualize the amoun t and change in strain during fault parallel flow deformation.
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Overview of the Move Tutorials
Tutor i al 27) Fault Analysis
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28) Geomechanical Modelling
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How to use the Fault Analysis module to colour map throw profiles, analyse the displacement on various plots, calculate the Shale Gouge Ratio and colour map rock type juxtapositions onto 3D faults. How to model palaeo-throw profiles and juxtapositions by using the 3D Decompaction and 3D Move-on-Fault tools to restore the section to a particular time period. How to collect a well log into the module, use the gamma ray log to determine the shale volume and calculate the Shale Gouge Ratio .
How to use the Geomechanical Modellingmodule to restore a 3D extensional fault block model by loading a pre-saved file with set up resotration parameters, inlcuding defined fault cutoffs. How to use the Strain Capture tool to colour map strain attributes on the surface and output a volume with numerical strain values. How to use the GeoVol tool to control the display of volumes.
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29) Fracture Modelling l
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How to use the Fracture Modellingmodule to build a discrete fracture network within a reservoir unit. How to use the stereo plot to analyse the orientation of observed fractures from well data and extract key statistical parameters. How to save properties such as porosity and permeability onto a volume and colour map using the GeoVol tool.
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How to use the Stress Analysis module to model slip tendency, slip stability, fracture stability and dilation tendency on two reverse faults and a discrete fracture network. How to import a well log with pore pressure attributes, update the stress state and monitor the resultant fracture stability.
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31) Fault Response Modelling
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How to use the Fault Response Modelling module to model displacement, strain, stress and shear/normal stress relationships on a normal fault in an elastic medium. How to visualize the outputs generated from the FRM simulation. How to analyse multiple faults at once and model fractures on the collected observation object.
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Overview of the Move Tutorials
Tutor ial 32) St Corneli Restoration and Fracture Generation
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How to restore the Sant Corneli Anticline using the Geomechanical Modelling module, and save the strai n attributes usi ng the Strain Capture tool. How to project the strain attributes onto a volume by converting 3D surfaces into a point cloud and using the Cell Attributes Analyser. How to use the Cell Attributes Analyser to re-scal e the e1 strain attribute so it can be used as a proxy for fracture intensity in the Fracture Modellingmodule. How to quality control the result of fracture modelling against real field data and compare the results with stereo plot analysis.
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To show how the Move Li nk for GS T allows users of Move to work directly with 3D data stored in GiGa infosystem’s GST Storage solution. To use the link to transfer data to and from Move.
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Provides a description of every tool present in the panels and toolbars of Move. Lists every keyboard shortcut available in Move, including shortcuts for the Basic Transform tool
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