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Add fault reactivation modeling

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jonjenssen
2023-05-03 02:20:05 +02:00
committed by Kristian Bendiksen
parent 14c37c4b2c
commit 32326bfa9b
43 changed files with 2626 additions and 157 deletions
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ApplicationLibCode/ReservoirDataModel/RigGriddedPart3d.cpp Normal file
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/////////////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2023 Equinor ASA
//
// ResInsight is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// ResInsight is distributed in the hope that it will be useful, but WITHOUT ANY
// WARRANTY; without even the implied warranty of MERCHANTABILITY or
// FITNESS FOR A PARTICULAR PURPOSE.
//
// See the GNU General Public License at <http://www.gnu.org/licenses/gpl.html>
// for more details.
//
/////////////////////////////////////////////////////////////////////////////////
#include "RigGriddedPart3d.h"
#include "cvfTextureImage.h"
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigGriddedPart3d::RigGriddedPart3d()
: m_thickness( 10.0 )
{
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigGriddedPart3d::~RigGriddedPart3d()
{
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RigGriddedPart3d::reset()
{
m_borderSurfaceElements.clear();
m_vertices.clear();
m_elementIndices.clear();
m_meshLines.clear();
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
cvf::Vec3d RigGriddedPart3d::stepVector( cvf::Vec3d start, cvf::Vec3d stop, int nSteps )
{
cvf::Vec3d vec = stop - start;
return vec.getNormalized() * ( vec.length() / nSteps );
}
//--------------------------------------------------------------------------------------------------
/// Point index in input
///
///
/// 3 ----------- 7 *
/// | | *
/// | | *
/// | | *
/// 2 |---------| 6 *
/// | \ *
/// | \ *
/// | \ *
/// 1 -------------| 5 *
/// | | *
/// | | *
/// | | *
/// | | *
/// 0 -------------- 4 *
///
/// Assumes 0->4, 1->5, 2->6 and 3->7 is parallel
///
///
//--------------------------------------------------------------------------------------------------
void RigGriddedPart3d::generateGeometry( std::vector<cvf::Vec3d> inputPoints, int nHorzCells, int nVertCellsLower, int nVertCellsMiddle, int nVertCellsUpper )
{
reset();
cvf::Vec3d step0to1 = stepVector( inputPoints[0], inputPoints[1], nVertCellsLower );
cvf::Vec3d step1to2 = stepVector( inputPoints[1], inputPoints[2], nVertCellsMiddle );
cvf::Vec3d step2to3 = stepVector( inputPoints[2], inputPoints[3], nVertCellsUpper );
cvf::Vec3d step4to5 = stepVector( inputPoints[4], inputPoints[5], nVertCellsLower );
cvf::Vec3d step5to6 = stepVector( inputPoints[5], inputPoints[6], nVertCellsMiddle );
cvf::Vec3d step6to7 = stepVector( inputPoints[6], inputPoints[7], nVertCellsUpper );
cvf::Vec3d step0to4 = stepVector( inputPoints[0], inputPoints[4], nHorzCells );
cvf::Vec3d tVec = step0to4 ^ step0to1;
tVec.normalize();
tVec *= m_thickness;
const std::vector<double> m_thicknessFactors = { -1.0, 0.0, 1.0 };
const int nThicknessCells = 2;
const int nVertCells = nVertCellsLower + nVertCellsMiddle + nVertCellsUpper;
const std::vector<int> vertCells = { nVertCellsLower, nVertCellsMiddle, nVertCellsUpper + 1 };
const std::vector<cvf::Vec3d> firstSteps = { step0to1, step1to2, step2to3 };
const std::vector<cvf::Vec3d> lastSteps = { step4to5, step5to6, step6to7 };
// ** generate vertices
m_vertices.reserve( (size_t)( ( nVertCells + 1 ) * ( nHorzCells + 1 ) ) );
cvf::Vec3d p = inputPoints[0];
cvf::Vec3d pLast = inputPoints[4];
for ( int i = 0; i < (int)vertCells.size(); i++ )
{
for ( int v = 0; v < vertCells[i]; v++ )
{
cvf::Vec3d stepHorz = stepVector( p, pLast, nHorzCells );
cvf::Vec3d p2 = p;
for ( int h = 0; h <= nHorzCells; h++ )
{
for ( int t = 0; t < (int)m_thicknessFactors.size(); t++ )
{
m_vertices.push_back( p2 + m_thicknessFactors[t] * tVec );
}
p2 += stepHorz;
pLast = p2;
}
p += firstSteps[i];
pLast += lastSteps[i];
}
}
// ** generate elements of type hex8
m_elementIndices.resize( (size_t)( nVertCells * nHorzCells * nThicknessCells ) );
m_borderSurfaceElements[BorderSurface::UpperSurface] = {};
m_borderSurfaceElements[BorderSurface::FaultSurface] = {};
m_borderSurfaceElements[BorderSurface::LowerSurface] = {};
int layerIndex = 0;
int elementIdx = 0;
BorderSurface currentRegion = BorderSurface::LowerSurface;
const int nextLayerIdxOff = ( nHorzCells + 1 ) * ( nThicknessCells + 1 );
const int nThicknessOff = nThicknessCells + 1;
for ( int v = 0; v < nVertCells; v++ )
{
if ( v >= nVertCellsLower ) currentRegion = BorderSurface::FaultSurface;
if ( v >= nVertCellsLower + nVertCellsMiddle ) currentRegion = BorderSurface::UpperSurface;
int i = layerIndex;
for ( int h = 0; h < nHorzCells; h++ )
{
for ( int t = 0; t < nThicknessCells; t++ )
{
m_elementIndices[elementIdx].push_back( t + i );
m_elementIndices[elementIdx].push_back( t + i + nThicknessOff );
m_elementIndices[elementIdx].push_back( t + i + nThicknessOff + 1 );
m_elementIndices[elementIdx].push_back( t + i + 1 );
m_elementIndices[elementIdx].push_back( t + nextLayerIdxOff + i );
m_elementIndices[elementIdx].push_back( t + nextLayerIdxOff + i + nThicknessOff );
m_elementIndices[elementIdx].push_back( t + nextLayerIdxOff + i + nThicknessOff + 1 );
m_elementIndices[elementIdx].push_back( t + nextLayerIdxOff + i + 1 );
elementIdx++;
}
i += nThicknessOff;
}
// add elements to border surface in current region
m_borderSurfaceElements[currentRegion].push_back( elementIdx - 2 );
m_borderSurfaceElements[currentRegion].push_back( elementIdx - 1 );
layerIndex += nextLayerIdxOff;
}
// generate meshlines for 2d viz
generateMeshlines( { inputPoints[0], inputPoints[1], inputPoints[5], inputPoints[4] }, nHorzCells, nVertCellsLower );
generateMeshlines( { inputPoints[1], inputPoints[2], inputPoints[6], inputPoints[5] }, nHorzCells, nVertCellsMiddle );
generateMeshlines( { inputPoints[2], inputPoints[3], inputPoints[7], inputPoints[6] }, nHorzCells, nVertCellsUpper );
}
//--------------------------------------------------------------------------------------------------
/// Point index in input
///
/// 1 ____________ 2
/// | /
/// | /
/// | /
/// | /
/// |_______/
/// 0 3
///
/// Assumes 0->3 and 1->2 is parallel
//--------------------------------------------------------------------------------------------------
void RigGriddedPart3d::generateMeshlines( std::vector<cvf::Vec3d> cornerPoints, int numHorzCells, int numVertCells )
{
cvf::Vec3d step0to1 = stepVector( cornerPoints[0], cornerPoints[1], numVertCells );
cvf::Vec3d step0to3 = stepVector( cornerPoints[0], cornerPoints[3], numHorzCells );
cvf::Vec3d step1to2 = stepVector( cornerPoints[1], cornerPoints[2], numHorzCells );
cvf::Vec3d step3to2 = stepVector( cornerPoints[3], cornerPoints[2], numVertCells );
// horizontal lines
cvf::Vec3d startP = cornerPoints[0];
cvf::Vec3d endP = cornerPoints[3];
for ( int v = 0; v <= numVertCells; v++ )
{
m_meshLines.push_back( { startP, endP } );
startP += step0to1;
endP += step3to2;
}
// vertical lines
startP = cornerPoints[0];
endP = cornerPoints[1];
for ( int h = 0; h <= numHorzCells; h++ )
{
m_meshLines.push_back( { startP, endP } );
startP += step0to3;
endP += step1to2;
}
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
const std::vector<cvf::Vec3d>& RigGriddedPart3d::vertices() const
{
return m_vertices;
}
//--------------------------------------------------------------------------------------------------
/// Output elements will be of type HEX8
///
/// 7---------6
/// /| /|
/// / | / |
/// 4---------5 | z
/// | 3------|--2 | y
/// | / | / | /
/// |/ |/ |/
/// 0---------1 ----- x
///
//--------------------------------------------------------------------------------------------------
const std::vector<std::vector<unsigned int>>& RigGriddedPart3d::elementIndices() const
{
return m_elementIndices;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
const std::map<RigGriddedPart3d::BorderSurface, std::vector<unsigned int>>& RigGriddedPart3d::borderSurfaceElements() const
{
return m_borderSurfaceElements;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
const std::vector<std::vector<cvf::Vec3d>>& RigGriddedPart3d::meshLines() const
{
return m_meshLines;
}