OilfieldToolsNet/ResInsight
4
0
Fork 0
mirror of https://github.com/OPM/ResInsight.git synced 2025-02-25 18:55:39 -06:00
Code Issues Packages Projects Releases Wiki Activity

#942 Added plane Azi and Inc angles as result values.

Browse Source
This commit is contained in:
Jacob Støren
2016-11-01 12:04:56 +01:00
parent 67894ecef0
commit d2d9d43ca1
5 changed files with 162 additions and 14 deletions
Download Patch File Download Diff File Expand all files Collapse all files

81
ApplicationCode/GeoMech/GeoMechDataModel/RigFemPartResultsCollection.cpp
View File

@@ -339,6 +339,8 @@ std::map<std::string, std::vector<std::string> > RigFemPartResultsCollection::sc
}
else if(resPos == RIG_ELEMENT_NODAL_FACE)
{
fieldCompNames["Plane"].push_back("Pinc");
fieldCompNames["Plane"].push_back("Pazi");
fieldCompNames["SE"].push_back("SN");
fieldCompNames["SE"].push_back("STH");
@@ -631,7 +633,6 @@ RigFemScalarResultFrames* RigFemPartResultsCollection::calculateSFI(int partInde
return dstDataFrames;
}
#define M_PI_4 0.785398163397448309616 // pi/4
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
@@ -670,7 +671,8 @@ RigFemScalarResultFrames* RigFemPartResultsCollection::calculateDSM(int partInde
{
float se1 = se1Data[vIdx];
float se3 = se3Data[vIdx];
float rho = 2.0f * atan( sqrt(( se1 + cohPrTanFricAngle)/(se3 + cohPrTanFricAngle)) - M_PI_4);
float pi_4 = 0.785398163397448309616f;
float rho = 2.0f * atan( sqrt(( se1 + cohPrTanFricAngle)/(se3 + cohPrTanFricAngle)) - pi_4);
{
dstFrameData[vIdx] = tan(rho)/tanFricAng;
@@ -1081,6 +1083,78 @@ RigFemScalarResultFrames* RigFemPartResultsCollection::calculateSurfaceAlignedSt
return requestedSurfStress;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RigFemScalarResultFrames* RigFemPartResultsCollection::calculateSurfaceAngles(int partIndex, const RigFemResultAddress& resVarAddr)
{
CVF_ASSERT(resVarAddr.componentName == "Pazi" || resVarAddr.componentName == "Pinc");
caf::ProgressInfo frameCountProgress(this->frameCount() * 1, "");
frameCountProgress.setProgressDescription("Calculating " + QString::fromStdString(resVarAddr.fieldName + ": " + resVarAddr.componentName));
RigFemScalarResultFrames * PaziFrames = m_femPartResults[partIndex]->createScalarResult(RigFemResultAddress(resVarAddr.resultPosType, resVarAddr.fieldName, "Pazi"));
RigFemScalarResultFrames * PincFrames = m_femPartResults[partIndex]->createScalarResult(RigFemResultAddress(resVarAddr.resultPosType, resVarAddr.fieldName, "Pinc"));
const RigFemPart * femPart = m_femParts->part(partIndex);
const std::vector<cvf::Vec3f>& nodeCoordinates = femPart->nodes().coordinates;
int frameCount = this->frameCount();
// HACK ! Todo : make it robust against other elements than Hex8
size_t valCount = femPart->elementCount() * 24; // Number of Elm Node Face results 24 = 4 * num faces = 3* numElmNodes
for ( int fIdx = 0; fIdx < frameCount; ++fIdx )
{
std::vector<float>& Pazi = PaziFrames->frameData(fIdx);
std::vector<float>& Pinc = PincFrames->frameData(fIdx);
Pazi.resize(valCount);
Pinc.resize(valCount);
int elementCount = femPart->elementCount();
for ( int elmIdx = 0; elmIdx < elementCount; ++elmIdx )
{
RigElementType elmType = femPart->elementType(elmIdx);
int faceCount = RigFemTypes::elmentFaceCount(elmType);
const int* elmNodeIndices = femPart->connectivities(elmIdx);
int elmNodFaceResIdxElmStart = elmIdx * 24; // HACK should get from part
for ( int lfIdx = 0; lfIdx < faceCount; ++lfIdx )
{
int faceNodeCount = 0;
const int* localElmNodeIndicesForFace = RigFemTypes::localElmNodeIndicesForFace(elmType, lfIdx, &faceNodeCount);
if ( faceNodeCount == 4 )
{
int elmNodFaceResIdxFaceStart = elmNodFaceResIdxElmStart + lfIdx*4; // HACK
cvf::Vec3f quadVxs[4];
quadVxs[0] = (nodeCoordinates[elmNodeIndices[localElmNodeIndicesForFace[0]]]);
quadVxs[1] = (nodeCoordinates[elmNodeIndices[localElmNodeIndicesForFace[1]]]);
quadVxs[2] = (nodeCoordinates[elmNodeIndices[localElmNodeIndicesForFace[2]]]);
quadVxs[3] = (nodeCoordinates[elmNodeIndices[localElmNodeIndicesForFace[3]]]);
cvf::Mat3f rotMx = cvf::GeometryTools::computePlaneHorizontalRotationMx(quadVxs[2] -quadVxs[0], quadVxs[3] - quadVxs[1]);
OffshoreSphericalCoords sphCoord(cvf::Vec3f(rotMx.rowCol(0,2), rotMx.rowCol(1,2), rotMx.rowCol(2,2))); // Use Ez from the matrix as plane normal
for ( int qIdx = 0; qIdx < 4; ++qIdx )
{
int elmNodFaceResIdx = elmNodFaceResIdxFaceStart + qIdx;
Pazi[elmNodFaceResIdx] = cvf::Math::toDegrees( sphCoord.azi() );
Pinc[elmNodFaceResIdx] = cvf::Math::toDegrees( sphCoord.inc() );
}
}
}
}
frameCountProgress.incrementProgress();
}
RigFemScalarResultFrames* requestedPlaneAngle = this->findOrLoadScalarResult(partIndex, resVarAddr);
return requestedPlaneAngle;
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
@@ -1291,6 +1365,9 @@ RigFemScalarResultFrames* RigFemPartResultsCollection::calculateDerivedResult(in
if(resVarAddr.resultPosType == RIG_ELEMENT_NODAL_FACE )
{
if (resVarAddr.componentName == "Pazi" || resVarAddr.componentName == "Pinc" )
return calculateSurfaceAngles(partIndex, resVarAddr);
else
return calculateSurfaceAlignedStress(partIndex, resVarAddr);
}

7
ApplicationCode/GeoMech/GeoMechDataModel/RigFemPartResultsCollection.h
View File

@@ -98,6 +98,7 @@ private:
RigFemScalarResultFrames* calculateVolumetricStrain(int partIndex, const RigFemResultAddress& resVarAddr);
RigFemScalarResultFrames* calculateDeviatoricStrain(int partIndex, const RigFemResultAddress& resVarAddr);
RigFemScalarResultFrames* calculateSurfaceAlignedStress(int partIndex, const RigFemResultAddress& resVarAddr);
RigFemScalarResultFrames* calculateSurfaceAngles(int partIndex, const RigFemResultAddress& resVarAddr);
RigFemScalarResultFrames* calculatePrincipalStressValues(int partIndex, const RigFemResultAddress &resVarAddr);
RigFemScalarResultFrames* calculatePrincipalStrainValues(int partIndex, const RigFemResultAddress &resVarAddr);
@@ -140,9 +141,9 @@ public:
}
float inc() { return incAziR[0];}
float azi() { return incAziR[1];}
float r() { return incAziR[2];}
float inc() const { return incAziR[0];}
float azi() const { return incAziR[1];}
float r() const { return incAziR[2];}
private:
std::array<float, 3> incAziR;

10
ApplicationCode/ModelVisualization/Intersections/RivIntersectionBoxPartMgr.cpp
View File

@@ -184,6 +184,15 @@ void RivIntersectionBoxPartMgr::updateCellResultColor(size_t timeStepIndex)
// Special direction sensitive result calculation
const cvf::Vec3fArray* triangelVxes = m_intersectionBoxGenerator->triangleVxes();
if ( resVarAddress.componentName == "Pazi" || resVarAddress.componentName == "Pinc" )
{
RivIntersectionPartMgr::calculatePlaneAngleTextureCoords(m_intersectionBoxFacesTextureCoords.p(),
triangelVxes,
resVarAddress,
mapper);
}
else
{
RivIntersectionPartMgr::calculateGeoMechTensorXfTextureCoords(m_intersectionBoxFacesTextureCoords.p(),
triangelVxes,
vertexWeights,
@@ -192,6 +201,7 @@ void RivIntersectionBoxPartMgr::updateCellResultColor(size_t timeStepIndex)
(int)timeStepIndex,
mapper);
}
}
RivScalarMapperUtils::applyTextureResultsToPart(m_intersectionBoxFaces.p(),
m_intersectionBoxFacesTextureCoords.p(),

55
ApplicationCode/ModelVisualization/Intersections/RivIntersectionPartMgr.cpp
View File

@@ -188,6 +188,15 @@ void RivIntersectionPartMgr::updateCellResultColor(size_t timeStepIndex)
// Special direction sensitive result calculation
const cvf::Vec3fArray* triangelVxes = m_crossSectionGenerator->triangleVxes();
if ( resVarAddress.componentName == "Pazi" || resVarAddress.componentName == "Pinc" )
{
RivIntersectionPartMgr::calculatePlaneAngleTextureCoords(m_crossSectionFacesTextureCoords.p(),
triangelVxes,
resVarAddress,
mapper);
}
else
{
RivIntersectionPartMgr::calculateGeoMechTensorXfTextureCoords(m_crossSectionFacesTextureCoords.p(),
triangelVxes,
vertexWeights,
@@ -196,6 +205,7 @@ void RivIntersectionPartMgr::updateCellResultColor(size_t timeStepIndex)
(int)timeStepIndex,
mapper);
}
}
RivScalarMapperUtils::applyTextureResultsToPart(m_crossSectionFaces.p(),
m_crossSectionFacesTextureCoords.p(),
@@ -287,6 +297,51 @@ void RivIntersectionPartMgr::calculateGeoMechTensorXfTextureCoords(cvf::Vec2fArr
}
//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RivIntersectionPartMgr::calculatePlaneAngleTextureCoords(cvf::Vec2fArray* textureCoords,
const cvf::Vec3fArray* triangelVertices,
const RigFemResultAddress& resVarAddress,
const cvf::ScalarMapper* mapper)
{
textureCoords->resize(triangelVertices->size());
cvf::Vec2f* rawPtr = textureCoords->ptr();
int vxCount = static_cast<int>(triangelVertices->size());
int triCount = vxCount/3;
std::function<float (const OffshoreSphericalCoords& )> operation;
if (resVarAddress.componentName == "Pazi")
{
operation = [](const OffshoreSphericalCoords& sphCoord) { return sphCoord.azi();};
}
else if ( resVarAddress.componentName == "Pinc" )
{
operation = [](const OffshoreSphericalCoords& sphCoord) { return sphCoord.inc();};
}
#pragma omp parallel for schedule(dynamic)
for ( int triangleIdx = 0; triangleIdx < triCount; ++triangleIdx )
{
int triangleVxStartIdx = triangleIdx*3;
const cvf::Vec3f* triangle = &((*triangelVertices)[triangleVxStartIdx]);
cvf::Mat3f rotMx = cvf::GeometryTools::computePlaneHorizontalRotationMx(triangle[1] - triangle[0], triangle[2] - triangle[0]);
OffshoreSphericalCoords sphCoord(cvf::Vec3f(rotMx.rowCol(0, 2), rotMx.rowCol(1, 2), rotMx.rowCol(2, 2))); // Use Ez from the matrix as plane normal
float angle = cvf::Math::toDegrees( operation(sphCoord));
cvf::Vec2f texCoord = (angle != std::numeric_limits<float>::infinity()) ? mapper->mapToTextureCoord(angle) : cvf::Vec2f(0.0f, 1.0f);
rawPtr[triangleVxStartIdx + 0] = texCoord;
rawPtr[triangleVxStartIdx + 1] = texCoord;
rawPtr[triangleVxStartIdx + 2] = texCoord;
}
}
//--------------------------------------------------------------------------------------------------
/// Calculates the texture coordinates in a "nearly" one dimensional texture.
/// Undefined values are coded with a y-texturecoordinate value of 1.0 instead of the normal 0.5

5
ApplicationCode/ModelVisualization/Intersections/RivIntersectionPartMgr.h
View File

@@ -89,6 +89,11 @@ public:
int timeStepIdx,
const cvf::ScalarMapper* mapper);
static void calculatePlaneAngleTextureCoords(cvf::Vec2fArray* textureCoords,
const cvf::Vec3fArray* triangelVertices,
const RigFemResultAddress& resVarAddress,
const cvf::ScalarMapper* mapper);
cvf::ref<RivIntersectionHexGridInterface> createHexGridInterface();
private: