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Introduction to Automatic Differentiation Plot production rate and pressure decay Compute transmissibilities on interior connections Below are links to the main categories, but feel free to use the full list of products found on the list to the left. Welcome to the official Chaos documentation site.
Slightly more elaborate version with plotting Use AD to solve the nonlinear Rosenbrock problem Use automatic differentation to assmble a linear system
Model 2 of the 10th SPE Comparative Solution Project Visualize the whole model including inactive cells Alternatively, use plotGridVolumes for the same purpose Initialise Complete Simulation Case From ECLIPSE Data Construct grid and properties from ECLIPSE-type input. Unstructured Grids in Corner-Point Format
Some grid routines produce corner-point input data Grids can be manipulated after creation Finding mappings between grid primitives Creating and visualizing a small realization of the model How to Read, Display, and Manipulate Corner-Point Grids show vertical permeability distributions
agglom: Flow and property-based coarse-grid generation adjoint: Two-phase, incompressible adjoint solvers ad-mechanics: Coupled flow and mechanics ad-props: PVT, fluid models and other properties for the AD-solvers ad-core: Automatic Differentiation Core Basic Grid Operations and Manipulations: Rectilinear/Curvilinear Grids
diagnostics: Flow diagnostics functionality dg: Discontinous Galerkin discretizations dfm: Discrete fracture matrix implementation deckformat: Reading and conversion of input decks compositional: Equation-of-state compositional solvers
incomp: Solvers for incompressible flow and transport hfm: Hierarchical and embedded fractures fvbiot: Consistent finite-volume discretizations for poroelasticity
msmfem: Multiscale Mixed Finite-Element method for pressure msfvm: Multiscale Finite-Volume method for pressure mrst-gui: Graphical user-interfaces for MRST mrst_api: API for writing C/C++ for MRST mpfa: Multi-point flux approximation solvers for pressure
vemmech: Mechanics for general grids using the virtual element method vem: Virtual element method on general grids upscaling: Upscaling of reservoir problems steady-state Steady-state upscaling of functions spe10: Access to the SPE10 benchmark case re-mpfa: Richards’ equation with multi-point flux
Contents ¶ PLOTTING Routines for visual inspection of grid geometry and field properties. For more interactive tools that buildUpon this functionality, see the mrst-gui module. DifferentRoutines allow for plotting of general unstructured grids, as well as dataLocated in cells, on faces or on nodes.
values – create the accompanying histogram using the VALUES vector.If not specified, the routine will pick values from CDataOf the current axes. ax – add colorbar to axes AX instead of current axis BoundaryFaces ( g, varargin ) ♮xtract boundary faces from set of grid cells.MrstColorbar mrstColorbar ( ax ) mrstColorbar (., values ) = mrstColorbar (., location ) = mrstColorbar (., location , logscale ) = mrstColorbar (., location , logscale , limits ) Parameters:
block – The coarse block to be plotted.PlotFaults – Two-element logical vector, the entries of which specifyWhether or not fault faces should be added to theGraphical output of the ‘block’ and its neighbours,DEFAULT: PlotFaults = TRUE() (attach fault facesTo both the ‘block’ and all of its neighbours).Alpha – (2 + max(find(PlotFaults)))-element numeric vector,Values in , specifying scalar transparency( AlphaData) values for the block, its neighbours, andThe fault faces of the ‘block’ and its neighbours,DEFAULT: Alpha = ONES() (no transparency in any ofThe final objects–all objects drawn opaquely).‘Any’ – Additional keyword arguments will be passed directly on toFunction patch meaning all properties supported byH – Handle to resulting patch objects. ) h = plotBlockAndNeighbors (.) Parameters: NB! SettingThis parameter will also reset the caxis accordingly.PlotBlockAndNeighbors ( CG , block ) plotBlockAndNeighbors ( CG , block , 'pn1' , 'pv1' .
IfSize(colour,1) = 1, then the same colour is used forOne (constant) indexed colour for each node in faces. any(size(colour,1) = )One (constant) indexed colour for each face in faces.This option supports flat face shading only. Only returned if specifically requested.
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