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Merge branch 'feature-vf-ext' into 'develop'

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Update of view factor generation using 2AI and 2LI methods plus CGAL for ray tracing

See merge request Development/openfoam!551
This commit is contained in:
Mattijs Janssens
2022-08-04 14:18:23 +00:00
parent 88da2d5877 c08fc5ecd9
commit 227727d413
15 changed files with 815 additions and 271 deletions
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19
applications/utilities/preProcessing/viewFactorsGen/Allwmake Executable file
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@ -0,0 +1,19 @@
#!/bin/sh
cd "${0%/*}" || exit # Run from this directory
. ${WM_PROJECT_DIR:?}/wmake/scripts/AllwmakeParseArguments # (error catching)
. ${WM_PROJECT_DIR:?}/wmake/scripts/have_cgal
#------------------------------------------------------------------------------
unset COMP_FLAGS LINK_FLAGS
if have_cgal
then
echo " found CGAL -- enabling CGAL support."
else
echo " did not find CGAL -- disabling CGAL functionality"
export COMP_FLAGS="-DNO_CGAL"
fi
wmake $targetType
#------------------------------------------------------------------------------

10
applications/utilities/preProcessing/viewFactorsGen/Make/options
View File

@ -1,10 +1,18 @@
include $(GENERAL_RULES)/cgal-header-only
EXE_INC = \
-Wno-old-style-cast \
$(COMP_FLAGS) \
${CGAL_INC} \
-DCGAL_HEADER_ONLY \
-I$(LIB_SRC)/finiteVolume/lnInclude \
-I$(LIB_SRC)/surfMesh/lnInclude \
-I$(LIB_SRC)/meshTools/lnInclude \
-I$(LIB_SRC)/parallel/distributed/lnInclude \
-I$(LIB_SRC)/parallel/distributed/lnInclude
EXE_LIBS = \
/* ${CGAL_LIBS} */ \
-lfiniteVolume \
-lsurfMesh \
-lmeshTools \

84
applications/utilities/preProcessing/viewFactorsGen/searchingEngine_CGAL.H Normal file
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@ -0,0 +1,84 @@
Random rndGen(653213);
// Determine mesh bounding boxes:
List<treeBoundBox> meshBb
(
1,
treeBoundBox
(
boundBox(coarseMesh.points(), false)
).extend(rndGen, 1e-3)
);
// Dummy bounds dictionary
dictionary dict;
dict.add("bounds", meshBb);
dict.add
(
"distributionType",
distributedTriSurfaceMesh::distributionTypeNames_
[
distributedTriSurfaceMesh::FROZEN
]
);
dict.add("mergeDistance", SMALL);
labelList triSurfaceToAgglom(5*nFineFaces);
triSurface localSurface = triangulate
(
patches,
includePatches,
finalAgglom,
triSurfaceToAgglom,
globalNumbering,
coarsePatches
);
// CGAL surface
distributedTriSurfaceMesh surfacesMesh
(
IOobject
(
"wallSurface.stl",
runTime.constant(), // directory
"triSurface", // instance
runTime, // registry
IOobject::NO_READ,
IOobject::NO_WRITE
),
localSurface,
dict
);
triSurfaceToAgglom.resize(surfacesMesh.size());
surfacesMesh.setField(triSurfaceToAgglom);
const pointField& pts = surfacesMesh.localPoints();
std::list<Triangle> triangles;
for (const auto& triLocal : surfacesMesh.localFaces())
{
point p1l = pts[triLocal[0]];
point p2l = pts[triLocal[1]];
point p3l = pts[triLocal[2]];
Point p1(p1l[0], p1l[1], p1l[2]);
Point p2(p2l[0], p2l[1], p2l[2]);
Point p3(p3l[0], p3l[1], p3l[2]);
Triangle tri(p1, p2, p3);
if (tri.is_degenerate())
{
std::cout << tri << std::endl;
}
triangles.push_back(tri);
}
// constructs AABB tree
Tree tree(triangles.begin(), triangles.end());

9
applications/utilities/preProcessing/viewFactorsGen/shootRays.H
View File

@ -1,6 +1,15 @@
// All rays expressed as start face (local) index end end face (global)
// Pre-size by assuming a certain percentage is visible.
if (Pstream::master())
{
Info<< "\nShooting rays using distributedTriSurfaceMesh (no CGAL support)"
<< endl;
}
// Maximum length for dynamicList
const label maxDynListLength
(

131
applications/utilities/preProcessing/viewFactorsGen/shootRays_CGAL.H Normal file
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@ -0,0 +1,131 @@
// Maximum length for dynamicList
const label maxDynListLength
(
viewFactorDict.getOrDefault<label>("maxDynListLength", 1000000000)
);
for (const int proci : Pstream::allProcs())
{
std::vector<Point> start;
start.reserve(coarseMesh.nFaces());
std::vector<Point> end(start.size());
end.reserve(start.size());
DynamicList<label> startIndex(start.size());
DynamicList<label> endIndex(start.size());
DynamicList<label> startAgg(start.size());
DynamicList<label> endAgg(start.size());
const pointField& myFc = remoteCoarseCf[Pstream::myProcNo()];
const vectorField& myArea = remoteCoarseSf[Pstream::myProcNo()];
const labelField& myAgg = remoteCoarseAgg[Pstream::myProcNo()];
const pointField& remoteArea = remoteCoarseSf[proci];
const pointField& remoteFc = remoteCoarseCf[proci];
const labelField& remoteAgg = remoteCoarseAgg[proci];
label i = 0;
label j = 0;
do
{
for (; i < myFc.size(); i++)
{
const point& fc = myFc[i];
const vector& fA = myArea[i];
const label& fAgg = myAgg[i];
for (; j < remoteFc.size(); j++)
{
if (proci != Pstream::myProcNo() || i != j)
{
const point& remFc = remoteFc[j];
const vector& remA = remoteArea[j];
const label& remAgg = remoteAgg[j];
const vector d(remFc - fc);
const vector nd = d/mag(d);
const vector nfA = fA/mag(fA);
const vector nremA = remA/mag(remA);
if (((nd & nfA) < 0) && ((nd & nremA) > 0))
{
vector direction(d[0], d[1], d[2]);
vector s(fc[0], fc[1], fc[2]);
vector rayEnd(s + (1-intTol)*direction);
end.push_back(Point(rayEnd[0], rayEnd[1], rayEnd[2]));
s += vector(intTol*d[0], intTol*d[1], intTol*d[2]);
start.push_back(Point(s[0], s[1], s[2]));
startIndex.append(i);
if (useAgglomeration)
{
startAgg.append
(
globalNumbering.toGlobal(proci, fAgg)
);
endAgg.append
(
globalNumbering.toGlobal(proci, remAgg)
);
}
label globalI = globalNumbering.toGlobal(proci, j);
endIndex.append(globalI);
if (startIndex.size() > maxDynListLength)
{
FatalErrorInFunction
<< "Dynamic list need from capacity."
<< "Actual size maxDynListLength : "
<< maxDynListLength
<< abort(FatalError);
}
}
}
}
if (j == remoteFc.size())
{
j = 0;
}
}
} while (i < myFc.size());
label totalRays(startIndex.size());
reduce(totalRays, sumOp<scalar>());
if (debug)
{
Pout<< "Number of rays :" << totalRays << endl;
}
for (unsigned long rayI = 0; rayI < start.size(); ++rayI)
{
Segment ray(start[rayI], end[rayI]);
Segment_intersection intersects = tree.any_intersection(ray);
if (!intersects)
{
rayStartFace.append(startIndex[rayI]);
rayEndFace.append(endIndex[rayI]);
}
}
start.clear();
if (debug)
{
Pout << "hits : " << rayStartFace.size()<< endl;
}
startIndex.clear();
end.clear();
endIndex.clear();
startAgg.clear();
endAgg.clear();
}

574
applications/utilities/preProcessing/viewFactorsGen/viewFactorsGen.C
View File

@ -31,14 +31,34 @@ Group
grpPreProcessingUtilities
Description
View factors are calculated based on a face agglomeration array
(finalAgglom generated by faceAgglomerate utility).
This view factors generation application uses a combined approach of
double area integral (2AI) and double linear integral (2LI). 2AI is used
when the two surfaces are 'far' apart and 2LI when they are 'close'.
2LI is integrated along edges using Gaussian quadrature.
The distance between faces is calculating a ratio between averaged areas
and the distance between face centres.
Each view factor between the agglomerated faces i and j (Fij) is calculated
using a double integral of the sub-areas composing the agglomeration.
The input from viewFactorsDict are:
The patches involved in the view factor calculation are taken from the
boundary file and should be part on the group viewFactorWall. ie.:
GaussQuadTol 0.1; // GaussQuad error
distTol 8; // R/Average(rm)
alpha 0.22; // Use for common edges for 2LI
For debugging purposes, the following entries can be set in viewFactorsDict:
writeViewFactorMatrix true;
writeFacesAgglomeration false;
dumpRays false;
writeViewFactorMatrix writes the sum of the VF on each face.
writeFacesAgglomeration writes the agglomeration
dumpRays dumps rays
The participating patches in the VF calculation have to be in the
'viewFactorWall' patch group (in the polyMesh/boundary file), e.g.
floor
{
@ -48,6 +68,9 @@ Description
startFace 3100;
}
Compile with -DNO_CGAL only if no CGAL present - CGAL AABB tree performs
better than the built-in octree.
\*---------------------------------------------------------------------------*/
#include "argList.H"
@ -56,21 +79,52 @@ Description
#include "surfaceFields.H"
#include "distributedTriSurfaceMesh.H"
#include "meshTools.H"
#include "constants.H"
#include "indirectPrimitivePatch.H"
#include "DynamicField.H"
#include "unitConversion.H"
#include "scalarMatrices.H"
#include "labelListIOList.H"
#include "scalarListIOList.H"
#include "singleCellFvMesh.H"
#include "IOmapDistribute.H"
using namespace Foam;
#ifndef NO_CGAL
// Silence boost bind deprecation warnings (before CGAL-5.2.1)
#include "CGAL/version.h"
#if defined(CGAL_VERSION_NR) && (CGAL_VERSION_NR < 1050211000)
#define BOOST_BIND_GLOBAL_PLACEHOLDERS
#endif
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/AABB_triangle_primitive.h>
#include <CGAL/Surface_mesh.h>
typedef CGAL::Simple_cartesian<double> K;
typedef K::Point_3 Point;
typedef K::Direction_3 Vector3C;
typedef K::Triangle_3 Triangle;
typedef K::Segment_3 Segment;
typedef std::list<Triangle>::iterator Iterator;
typedef CGAL::AABB_triangle_primitive<K, Iterator> Primitive;
typedef CGAL::AABB_traits<K, Primitive> AABB_triangle_traits;
typedef CGAL::AABB_tree<AABB_triangle_traits> Tree;
typedef boost::optional
<
Tree::Intersection_and_primitive_id<Segment>::Type
> Segment_intersection;
#endif // NO_CGAL
using namespace Foam;
using namespace Foam::constant;
using namespace Foam::constant::mathematical;
triSurface triangulate
(
@ -127,20 +181,56 @@ triSurface triangulate
newPatchI++;
}
//striSurfaceToAgglom.resize(localTriFaceI-1);
//triSurfaceToAgglom.resize(localTriFaceI-1);
triangles.shrink();
triSurface surface(triangles, mesh.points());
surface.compactPoints();
// Create globally numbered tri surface
triSurface rawSurface(triangles, mesh.points());
// Create locally numbered tri surface
triSurface surface
#ifndef NO_CGAL
// CGAL : every processor has whole surface
globalIndex globalFaceIdx(surface.size(), globalIndex::gatherOnly());
globalIndex globalPointIdx
(
rawSurface.localFaces(),
rawSurface.localPoints()
surface.points().size(), globalIndex::gatherOnly()
);
List<labelledTri> globalSurfaceTris(globalFaceIdx.gather(surface));
pointField globalSurfacePoints(globalPointIdx.gather(surface.points()));
//label offset = 0;
for (const label proci : globalPointIdx.allProcs())
{
const label offset = globalPointIdx.localStart(proci);
if (offset)
{
for
(
labelledTri& tri
: globalSurfaceTris.slice(globalFaceIdx.range(proci))
)
{
tri[0] += offset;
tri[1] += offset;
tri[2] += offset;
}
}
}
surface =
triSurface
(
std::move(globalSurfaceTris),
std::move(globalSurfacePoints)
);
Pstream::broadcast(surface);
#endif
// Add patch names to surface
surface.patches().setSize(newPatchI);
@ -193,7 +283,7 @@ void writeRays
}
scalar calculateViewFactorFij
scalar calculateViewFactorFij2AI
(
const vector& i,
const vector& j,
@ -250,6 +340,74 @@ void insertMatrixElements
}
scalar GaussQuad
(
const scalarList& w,
const scalarList& p,
const scalar& magSi,
const scalar& magSj,
const vector& di,
const vector& dj,
const vector& ci,
const vector& cj,
const scalar cosij,
const scalar alpha,
label gi
)
{
scalar dIntFij = 0;
if (gi == 0)
{
vector r(ci - cj);
if (mag(r) < SMALL)
{
r = (alpha*magSi)*di;
}
dIntFij = max(cosij*Foam::log(r&r)*magSi*magSj, 0);
}
else
{
List<vector> pi(w.size());
forAll (pi, i)
{
pi[i] = ci + p[i]*(magSi/2)*di;
}
List<vector> pj(w.size());
forAll (pj, i)
{
pj[i] = cj + p[i]*(magSj/2)*dj;
}
forAll (w, i)
{
forAll (w, j)
{
vector r(pi[i] - pj[j]);
if (mag(r) < SMALL)
{
r = (alpha*magSi)*di;
dIntFij +=
cosij*w[i]*w[j]*Foam::log(r&r);
}
else
{
dIntFij +=
cosij*w[i]*w[j]*Foam::log(r&r);
}
}
}
dIntFij *= (magSi/2) * (magSj/2);
}
return dIntFij;
}
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
int main(int argc, char *argv[])
@ -273,7 +431,7 @@ int main(int argc, char *argv[])
"viewFactorsDict",
runTime.constant(),
mesh,
IOobject::MUST_READ_IF_MODIFIED,
IOobject::MUST_READ,
IOobject::NO_WRITE
)
);
@ -288,6 +446,23 @@ int main(int argc, char *argv[])
const label debug = viewFactorDict.getOrDefault<label>("debug", 0);
const scalar GaussQuadTol =
viewFactorDict.getOrDefault<scalar>("GaussQuadTol", 0.01);
const scalar distTol =
viewFactorDict.getOrDefault<scalar>("distTol", 8);
const scalar alpha =
viewFactorDict.getOrDefault<scalar>("alpha", 0.21);
const scalar intTol =
viewFactorDict.getOrDefault<scalar>("intTol", 1e-2);
bool useAgglomeration(true);
const polyBoundaryMesh& patches = mesh.boundaryMesh();
const labelList viewFactorsPatches(patches.indices(viewFactorWall));
// Read agglomeration map
labelListIOList finalAgglom
(
@ -296,12 +471,22 @@ int main(int argc, char *argv[])
"finalAgglom",
mesh.facesInstance(),
mesh,
IOobject::MUST_READ,
IOobject::READ_IF_PRESENT,
IOobject::NO_WRITE,
false
)
);
if (!finalAgglom.typeHeaderOk<labelListIOList>())
{
finalAgglom.setSize(patches.size());
for (label patchi=0; patchi < patches.size(); patchi++)
{
finalAgglom[patchi] = identity(patches[patchi].size());
}
useAgglomeration = false;
}
// Create the coarse mesh using agglomeration
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@ -336,10 +521,8 @@ int main(int argc, char *argv[])
label nCoarseFaces = 0; //total number of coarse faces
label nFineFaces = 0; //total number of fine faces
const polyBoundaryMesh& patches = mesh.boundaryMesh();
const polyBoundaryMesh& coarsePatches = coarseMesh.boundaryMesh();
labelList viewFactorsPatches(patches.indices(viewFactorWall));
for (const label patchi : viewFactorsPatches)
{
nCoarseFaces += coarsePatches[patchi].size();
@ -465,7 +648,13 @@ int main(int argc, char *argv[])
// Set up searching engine for obstacles
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
#ifdef NO_CGAL
// Using octree
#include "searchingEngine.H"
#else
// Using CGAL aabbtree (faster, more robust)
#include "searchingEngine_CGAL.H"
#endif
// Determine rays between coarse face centres
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@ -473,11 +662,15 @@ int main(int argc, char *argv[])
DynamicList<label> rayEndFace(rayStartFace.size());
// Return rayStartFace in local index and rayEndFace in global index
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
#ifdef NO_CGAL
// Using octree, distributedTriSurfaceMesh
#include "shootRays.H"
#else
// Using CGAL aabbtree (faster, more robust)
#include "shootRays_CGAL.H"
#endif
// Calculate number of visible faces from local index
labelList nVisibleFaceFaces(nCoarseFaces, Zero);
@ -518,9 +711,9 @@ int main(int argc, char *argv[])
visibleFaceFaces[faceI][nVisibleFaceFaces[faceI]++] = compactI;
}
// Construct data in compact addressing
// I need coarse Sf (Ai), fine Sf (dAi) and fine Cf(r) to calculate Fij
// (2AA) need coarse (Ai), fine Sf (dAi) and fine Cf(r) to calculate Fij
// (2LI) need edges (li)
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
pointField compactCoarseCf(map.constructSize(), Zero);
@ -528,12 +721,16 @@ int main(int argc, char *argv[])
List<List<point>> compactFineSf(map.constructSize());
List<List<point>> compactFineCf(map.constructSize());
DynamicList<List<point>> compactPoints(map.constructSize());
DynamicList<label> compactPatchId(map.constructSize());
// Insert my coarse local values
SubList<point>(compactCoarseSf, nCoarseFaces) = localCoarseSf;
SubList<point>(compactCoarseCf, nCoarseFaces) = localCoarseCf;
const faceList& faces = mesh.faces();
// Insert my fine local values
label compactI = 0;
forAll(viewFactorsPatches, i)
@ -548,11 +745,21 @@ int main(int argc, char *argv[])
const labelList& coarsePatchFace =
coarseMesh.patchFaceMap()[patchID];
const polyPatch& pp = patches[patchID];
forAll(coarseToFine, coarseI)
{
compactPatchId.append(patchID);
List<point>& fineCf = compactFineCf[compactI];
List<point>& fineSf = compactFineSf[compactI++];
List<point>& fineSf = compactFineSf[compactI];
label startFace = pp.start();
const vectorField locPoints
(
mesh.points(),
faces[coarseI + startFace]
);
const label coarseFaceI = coarsePatchFace[coarseI];
const labelList& fineFaces = coarseToFine[coarseFaceI];
@ -560,6 +767,8 @@ int main(int argc, char *argv[])
fineCf.setSize(fineFaces.size());
fineSf.setSize(fineFaces.size());
compactPoints.append(locPoints);
fineCf = UIndirectList<point>
(
mesh.Cf().boundaryField()[patchID],
@ -570,19 +779,25 @@ int main(int argc, char *argv[])
mesh.Sf().boundaryField()[patchID],
coarseToFine[coarseFaceI]
);
compactI++;
}
}
}
if (Pstream::master() && debug)
{
Info<< "map distribute..." << endl;
}
// Do all swapping
map.distribute(compactCoarseSf);
map.distribute(compactCoarseCf);
map.distribute(compactFineCf);
map.distribute(compactFineSf);
map.distribute(compactPoints);
map.distribute(compactPatchId);
// Plot all rays between visible faces.
if (dumpRays)
{
@ -598,8 +813,7 @@ int main(int argc, char *argv[])
// Fill local view factor matrix
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
scalarListIOList F
scalarListIOList F2LI
(
IOobject
(
@ -630,6 +844,61 @@ int main(int argc, char *argv[])
Info<< "\nCalculating view factors..." << endl;
}
FixedList<scalarList, 5> GaussPoints;
GaussPoints[0].setSize(1);
GaussPoints[0] = 0;
GaussPoints[1].setSize(2);
GaussPoints[1][0] = 1/std::sqrt(3);
GaussPoints[1][1] = -1/std::sqrt(3);
GaussPoints[2].setSize(3);
GaussPoints[2][0] = 0;
GaussPoints[2][1] = std::sqrt(3.0/5.0);
GaussPoints[2][2] = -std::sqrt(3.0/5.0);
GaussPoints[3].setSize(4);
GaussPoints[3][0] = std::sqrt(3.0/7.0 - (2.0/7.0)*std::sqrt(6.0/5.0));
GaussPoints[3][1] = -GaussPoints[3][0];
GaussPoints[3][2] = std::sqrt(3.0/7.0 + (2.0/7.0)*std::sqrt(6.0/5.0));
GaussPoints[3][3] = -GaussPoints[3][2];
GaussPoints[4].setSize(5);
GaussPoints[4][0] = 0;
GaussPoints[4][1] = (1.0/3.0)*std::sqrt(5.0 - 2.0*std::sqrt(10.0/7.0));
GaussPoints[4][2] = -GaussPoints[4][1];
GaussPoints[4][3] = (1.0/3.0)*std::sqrt(5.0 + 2.0*std::sqrt(10.0/7.0));
GaussPoints[4][4] = -GaussPoints[4][3];
List<scalarList> GaussWeights(5);
GaussWeights[0].setSize(1);
GaussWeights[0] = 2;
GaussWeights[1].setSize(2);
GaussWeights[1][0] = 1;
GaussWeights[1][1] = 1;
GaussWeights[2].setSize(3);
GaussWeights[2][0] = 8.0/9.0;
GaussWeights[2][1] = 5.0/9.0;
GaussWeights[2][2] = 5.0/9.0;
GaussWeights[3].setSize(4);
GaussWeights[3][0] = (18.0 + std::sqrt(30))/36.0;
GaussWeights[3][1] = (18.0 + std::sqrt(30))/36.0;
GaussWeights[3][2] = (18.0 - std::sqrt(30))/36.0;
GaussWeights[3][3] = (18.0 - std::sqrt(30))/36.0;
GaussWeights[4].setSize(5);
GaussWeights[4][0] = 128.0/225.0;
GaussWeights[4][1] = (322.0 + 13.0*std::sqrt(70))/900.0;
GaussWeights[4][2] = (322.0 + 13.0*std::sqrt(70))/900.0;
GaussWeights[4][3] = (322.0 - 13.0*std::sqrt(70))/900.0;
GaussWeights[4][4] = (322.0 - 13.0*std::sqrt(70))/900.0;
const label maxQuadOrder = 5;
if (mesh.nSolutionD() == 3)
{
forAll(localCoarseSf, coarseFaceI)
@ -638,119 +907,207 @@ int main(int argc, char *argv[])
const vector Ai = sum(localFineSf);
const List<point>& localFineCf = compactFineCf[coarseFaceI];
const label fromPatchId = compactPatchId[coarseFaceI];
const List<point>& lPoints = compactPoints[coarseFaceI];
patchArea[fromPatchId] += mag(Ai);
const labelList& visCoarseFaces = visibleFaceFaces[coarseFaceI];
forAll(visCoarseFaces, visCoarseFaceI)
{
F[coarseFaceI].setSize(visCoarseFaces.size());
//F2AI[coarseFaceI].setSize(visCoarseFaces.size());
F2LI[coarseFaceI].setSize(visCoarseFaces.size());
label compactJ = visCoarseFaces[visCoarseFaceI];
const List<point>& remoteFineSj = compactFineSf[compactJ];
const List<point>& remoteFineCj = compactFineCf[compactJ];
const List<point>& rPointsCj = compactPoints[compactJ];
const label toPatchId = compactPatchId[compactJ];
scalar Fij = 0;
bool far(false);
// Relative distance
forAll(localFineSf, i)
{
const vector& dAi = localFineSf[i];
const scalar dAi =
Foam::sqrt
(
mag(localFineSf[i])/constant::mathematical::pi
);
const vector& dCi = localFineCf[i];
forAll(remoteFineSj, j)
{
const vector& dAj = remoteFineSj[j];
const scalar dAj =
Foam::sqrt
(
mag(remoteFineSj[j])/constant::mathematical::pi
);
const vector& dCj = remoteFineCj[j];
scalar dIntFij = calculateViewFactorFij
(
dCi,
dCj,
dAi,
dAj
);
const scalar dist = mag(dCi - dCj)/((dAi + dAj)/2);
Fij += dIntFij;
if (dist > distTol)
{
far = true;
}
}
}
F[coarseFaceI][visCoarseFaceI] = Fij/mag(Ai);
sumViewFactorPatch[fromPatchId][toPatchId] += Fij;
if (far)
{
// 2AI method
scalar F2AIij = 0;
forAll(localFineSf, i)
{
const vector& dAi = localFineSf[i];
const vector& dCi = localFineCf[i];
forAll(remoteFineSj, j)
{
const vector& dAj = remoteFineSj[j];
const vector& dCj = remoteFineCj[j];
scalar dIntFij = calculateViewFactorFij2AI
(
dCi,
dCj,
dAi,
dAj
);
F2AIij += dIntFij;
}
}
F2LI[coarseFaceI][visCoarseFaceI] = F2AIij/mag(Ai);
}
else
{
// 2LI method
label nLocal = lPoints.size();
label nRemote = rPointsCj.size();
// Using sub-divisions (quadrature)
scalar oldEToeInt = 0;
for (label gi=0; gi < maxQuadOrder; gi++)
{
scalar F2LIij = 0;
for(label i=0; i<nLocal; i++)
{
vector si;
vector ci;
vector sj;
vector cj;
if (i == 0)
{
si = lPoints[i] - lPoints[nLocal-1];
ci = (lPoints[i] + lPoints[nLocal-1])/2;
}
else
{
si = lPoints[i] - lPoints[i-1];
ci = (lPoints[i] + lPoints[i-1])/2;
}
for(label j=0; j<nRemote; j++)
{
if (j == 0)
{
sj = rPointsCj[j]-rPointsCj[nRemote-1];
cj = (rPointsCj[j]+rPointsCj[nRemote-1])/2;
}
else
{
sj = rPointsCj[j] - rPointsCj[j-1];
cj = (rPointsCj[j] + rPointsCj[j-1])/2;
}
scalar magSi = mag(si);
scalar magSj = mag(sj);
scalar cosij = (si & sj)/(magSi * magSj);
vector di = si/magSi;
vector dj = sj/magSj;
label quadOrder = gi;
const vector r(ci - cj);
// Common edges use n = 0
if (mag(r) < SMALL)
{
quadOrder = 0;
}
scalar dIntFij =
GaussQuad
(
GaussWeights[gi],
GaussPoints[gi],
magSi,
magSj,
di,
dj,
ci,
cj,
cosij,
alpha,
quadOrder
);
F2LIij += dIntFij;
}
}
scalar err = (F2LIij-oldEToeInt)/F2LIij;
if
(
(mag(err) < GaussQuadTol && gi > 0)
|| gi == maxQuadOrder-1
)
{
F2LI[coarseFaceI][visCoarseFaceI] =
F2LIij/mag(Ai)/4/constant::mathematical::pi;
break;
}
else
{
oldEToeInt = F2LIij;
}
}
}
sumViewFactorPatch[fromPatchId][toPatchId] +=
F2LI[coarseFaceI][visCoarseFaceI]*mag(Ai);
}
}
}
else if (mesh.nSolutionD() == 2)
else
{
const boundBox& box = mesh.bounds();
const Vector<label>& dirs = mesh.geometricD();
vector emptyDir = Zero;
forAll(dirs, i)
{
if (dirs[i] == -1)
{
emptyDir[i] = 1.0;
}
}
scalar wideBy2 = (box.span() & emptyDir)*2.0;
forAll(localCoarseSf, coarseFaceI)
{
const vector& Ai = localCoarseSf[coarseFaceI];
const vector& Ci = localCoarseCf[coarseFaceI];
vector Ain = Ai/mag(Ai);
vector R1i = Ci + (mag(Ai)/wideBy2)*(Ain ^ emptyDir);
vector R2i = Ci - (mag(Ai)/wideBy2)*(Ain ^ emptyDir) ;
const label fromPatchId = compactPatchId[coarseFaceI];
patchArea[fromPatchId] += mag(Ai);
const labelList& visCoarseFaces = visibleFaceFaces[coarseFaceI];
forAll(visCoarseFaces, visCoarseFaceI)
{
F[coarseFaceI].setSize(visCoarseFaces.size());
label compactJ = visCoarseFaces[visCoarseFaceI];
const vector& Aj = compactCoarseSf[compactJ];
const vector& Cj = compactCoarseCf[compactJ];
const label toPatchId = compactPatchId[compactJ];
vector Ajn = Aj/mag(Aj);
vector R1j = Cj + (mag(Aj)/wideBy2)*(Ajn ^ emptyDir);
vector R2j = Cj - (mag(Aj)/wideBy2)*(Ajn ^ emptyDir);
scalar d1 = mag(R1i - R2j);
scalar d2 = mag(R2i - R1j);
scalar s1 = mag(R1i - R1j);
scalar s2 = mag(R2i - R2j);
scalar Fij = mag((d1 + d2) - (s1 + s2))/(4.0*mag(Ai)/wideBy2);
F[coarseFaceI][visCoarseFaceI] = Fij;
sumViewFactorPatch[fromPatchId][toPatchId] += Fij*mag(Ai);
}
}
}
if (Pstream::master())
{
Info << "Writing view factor matrix..." << endl;
FatalErrorInFunction
<< " View factors are not available in 2D "
<< exit(FatalError);
}
// Write view factors matrix in listlist form
F.write();
F2LI.write();
reduce(sumViewFactorPatch, sumOp<scalarSquareMatrix>());
reduce(patchArea, sumOp<scalarList>());
if (Pstream::master() && debug)
{
forAll(viewFactorsPatches, i)
{
label patchI = viewFactorsPatches[i];
forAll(viewFactorsPatches, i)
for (label j=i; j<viewFactorsPatches.size(); j++)
{
label patchJ = viewFactorsPatches[i];
label patchJ = viewFactorsPatches[j];
Info << "F" << patchI << patchJ << ": "
<< sumViewFactorPatch[patchI][patchJ]/patchArea[patchI]
<< endl;
@ -758,9 +1115,13 @@ int main(int argc, char *argv[])
}
}
if (writeViewFactors)
{
if (Pstream::master())
{
Info << "Writing view factor matrix..." << endl;
}
volScalarField viewFactorField
(
IOobject
@ -791,13 +1152,14 @@ int main(int argc, char *argv[])
forAll(coarseToFine, coarseI)
{
const scalar Fij = sum(F[compactI]);
const scalar FiSum = sum(F2LI[compactI]);
const label coarseFaceID = coarsePatchFace[coarseI];
const labelList& fineFaces = coarseToFine[coarseFaceID];
forAll(fineFaces, fineId)
{
const label faceID = fineFaces[fineId];
vfbf[patchID][faceID] = Fij;
vfbf[patchID][faceID] = FiSum;
}
compactI++;
}

111
src/thermophysicalModels/radiation/radiationModels/viewFactor/viewFactor.C
View File

@ -35,6 +35,8 @@ License
#include "boundaryRadiationProperties.H"
#include "lduCalculatedProcessorField.H"
using namespace Foam::constant;
// * * * * * * * * * * * * * * Static Data Members * * * * * * * * * * * * * //
@ -55,7 +57,36 @@ const Foam::word Foam::radiation::viewFactor::viewFactorWalls
void Foam::radiation::viewFactor::initialise()
{
const polyBoundaryMesh& coarsePatches = coarseMesh_.boundaryMesh();
const polyBoundaryMesh& patches = mesh_.boundaryMesh();
if (!finalAgglom_.typeHeaderOk<labelListIOList>())
{
finalAgglom_.setSize(patches.size());
for (label patchi=0; patchi < patches.size(); patchi++)
{
finalAgglom_[patchi] = identity(patches[patchi].size());
}
}
coarseMesh_.reset
(
new singleCellFvMesh
(
IOobject
(
"coarse:" + mesh_.name(),
mesh_.polyMesh::instance(),
mesh_.time(),
IOobject::NO_READ,
IOobject::NO_WRITE,
false
),
mesh_,
finalAgglom_
)
);
const polyBoundaryMesh& coarsePatches = coarseMesh_->boundaryMesh();
selectedPatches_ = mesh_.boundaryMesh().indices(viewFactorWalls);
@ -80,6 +111,8 @@ void Foam::radiation::viewFactor::initialise()
useDirect_ = coeffs_.getOrDefault<bool>("useDirectSolver", true);
map_.reset
(
new IOmapDistribute
@ -186,7 +219,7 @@ void Foam::radiation::viewFactor::initialise()
labelList upper(rays_.size(), -1);
labelList lower(rays_.size(), -1);
const edgeList& raysLst = rays_.sortedToc();
const edgeList raysLst(rays_.sortedToc());
label rayI = 0;
for (const auto& e : raysLst)
{
@ -408,8 +441,8 @@ void Foam::radiation::viewFactor::initialise()
totalDelta /= myF.size();
reduce(totalDelta, sumOp<scalar>());
reduce(maxDelta, maxOp<scalar>());
Info << "Smoothng average delta : " << totalDelta << endl;
Info << "Smoothng maximum delta : " << maxDelta << nl << endl;
Info << "Smoothing average delta : " << totalDelta << endl;
Info << "Smoothing maximum delta : " << maxDelta << nl << endl;
}
}
@ -510,26 +543,26 @@ Foam::radiation::viewFactor::viewFactor(const volScalarField& T)
"finalAgglom",
mesh_.facesInstance(),
mesh_,
IOobject::MUST_READ,
IOobject::READ_IF_PRESENT,
IOobject::NO_WRITE,
false
)
),
map_(),
coarseMesh_
(
IOobject
(
"coarse:" + mesh_.name(),
mesh_.polyMesh::instance(),
mesh_.time(),
IOobject::NO_READ,
IOobject::NO_WRITE,
false
),
mesh_,
finalAgglom_
),
coarseMesh_(),
// (
// IOobject
// (
// "coarse:" + mesh_.name(),
// mesh_.polyMesh::instance(),
// mesh_.time(),
// IOobject::NO_READ,
// IOobject::NO_WRITE,
// false
// ),
// mesh_,
// finalAgglom_
// ),
qr_
(
IOobject
@ -573,26 +606,26 @@ Foam::radiation::viewFactor::viewFactor
"finalAgglom",
mesh_.facesInstance(),
mesh_,
IOobject::MUST_READ,
IOobject::READ_IF_PRESENT,
IOobject::NO_WRITE,
false
)
),
map_(),
coarseMesh_
(
IOobject
(
"coarse:" + mesh_.name(),
mesh_.polyMesh::instance(),
mesh_.time(),
IOobject::NO_READ,
IOobject::NO_WRITE,
false
),
mesh_,
finalAgglom_
),
coarseMesh_(),
// (
// IOobject
// (
// "coarse:" + mesh_.name(),
// mesh_.polyMesh::instance(),
// mesh_.time(),
// IOobject::NO_READ,
// IOobject::NO_WRITE,
// false
// ),
// mesh_,
// finalAgglom_
// ),
qr_
(
IOobject
@ -719,10 +752,10 @@ void Foam::radiation::viewFactor::calculate()
const tmp<scalarField> tHoi = qrp.qro(bandI);
const scalarField& Hoi = tHoi();
const polyPatch& pp = coarseMesh_.boundaryMesh()[patchID];
const polyPatch& pp = coarseMesh_->boundaryMesh()[patchID];
const labelList& coarsePatchFace =
coarseMesh_.patchFaceMap()[patchID];
coarseMesh_->patchFaceMap()[patchID];
scalarList T4ave(pp.size(), 0.0);
scalarList Eave(pp.size(), 0.0);
@ -820,7 +853,7 @@ void Foam::radiation::viewFactor::calculate()
// Local matrix coefficients
if (!constEmissivity_ || iterCounter_ == 0)
{
const edgeList& raysLst = rays_.sortedToc();
const edgeList raysLst(rays_.sortedToc());
label rayI = 0;
for (const auto& e : raysLst)
@ -1044,7 +1077,7 @@ void Foam::radiation::viewFactor::calculate()
label globCoarseId = 0;
for (const label patchID : selectedPatches_)
{
const polyPatch& pp = coarseMesh_.boundaryMesh()[patchID];
const polyPatch& pp = coarseMesh_->boundaryMesh()[patchID];
if (pp.size() > 0)
{
@ -1056,7 +1089,7 @@ void Foam::radiation::viewFactor::calculate()
labelListList coarseToFine(invertOneToMany(nAgglom, agglom));
const labelList& coarsePatchFace =
coarseMesh_.patchFaceMap()[patchID];
coarseMesh_->patchFaceMap()[patchID];
//scalar heatFlux = 0.0;
forAll(coarseToFine, coarseI)

4
src/thermophysicalModels/radiation/radiationModels/viewFactor/viewFactor.H
View File

@ -6,7 +6,7 @@
\\/ M anipulation |
-------------------------------------------------------------------------------
Copyright (C) 2011-2017 OpenFOAM Foundation
Copyright (C) 2018 OpenCFD Ltd.
Copyright (C) 2018-2022 OpenCFD Ltd.
-------------------------------------------------------------------------------
License
This file is part of OpenFOAM.
@ -107,7 +107,7 @@ protected:
autoPtr<IOmapDistribute> map_;
//- Coarse mesh
singleCellFvMesh coarseMesh_;
autoPtr<singleCellFvMesh> coarseMesh_;
//- Net radiative heat flux [W/m2]
volScalarField qr_;

10
tutorials/heatTransfer/chtMultiRegionFoam/externalSolarLoad/Allrun
View File

@ -9,11 +9,11 @@ cd "${0%/*}" || exit # Run from this directory
#-- Run on single processor
# Agglomerate patch faces
for region in air
do
runApplication -s $region \
faceAgglomerate -region $region -dict constant/viewFactorsDict
done
#for region in air
#do
# runApplication -s $region \
# faceAgglomerate -region $region -dict constant/viewFactorsDict
#done
# Generate view factors
for region in air

10
tutorials/heatTransfer/chtMultiRegionFoam/externalSolarLoad/Allrun-parallel
View File

@ -12,11 +12,11 @@ cd "${0%/*}" || exit # Run from this directory
runApplication decomposePar -allRegions -constant
# Agglomerate patch faces
for region in air
do
runParallel -s $region \
faceAgglomerate -region $region -dict constant/viewFactorsDict
done
#for region in air
#do
# runParallel -s $region \
# faceAgglomerate -region $region -dict constant/viewFactorsDict
#done
# Generate view factors
for region in air

3
tutorials/heatTransfer/chtMultiRegionFoam/externalSolarLoad/constant/air/viewFactorsDict
View File

@ -15,11 +15,10 @@ FoamFile
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
writeViewFactorMatrix true;
writeFacesAgglomeration true;
writePatchViewFactors false;
// dumpRays true;
maxDynListLength 200000;
maxDynListLength 200000;
// ************************************************************************* //

10
tutorials/heatTransfer/chtMultiRegionSimpleFoam/multiRegionHeaterRadiation/Allrun
View File

@ -9,11 +9,11 @@ cd "${0%/*}" || exit # Run from this directory
#-- Run on single processor
# Agglomerate patch faces
for region in bottomAir topAir
do
runApplication -s "$region" \
faceAgglomerate -region "$region" -dict constant/viewFactorsDict
done
#for region in bottomAir topAir
#do
# runApplication -s "$region" \
# faceAgglomerate -region "$region" -dict constant/viewFactorsDict
#done
# Generate view factors
for region in bottomAir topAir

10
tutorials/heatTransfer/chtMultiRegionSimpleFoam/multiRegionHeaterRadiation/Allrun-parallel
View File

@ -12,11 +12,11 @@ cd "${0%/*}" || exit # Run from this directory
runApplication decomposePar -allRegions
# Agglomerate patch faces
for region in bottomAir topAir
do
runParallel -s "$region" \
faceAgglomerate -region "$region" -dict constant/viewFactorsDict
done
#for region in bottomAir topAir
#do
# runParallel -s "$region" \
# faceAgglomerate -region "$region" -dict constant/viewFactorsDict
#done
# Generate view factors
for region in bottomAir topAir

50
tutorials/heatTransfer/chtMultiRegionSimpleFoam/multiRegionHeaterRadiation/constant/bottomAir/viewFactorsDict
View File

@ -15,56 +15,6 @@ FoamFile
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
writeViewFactorMatrix true;
writeFacesAgglomeration true;
writePatchViewFactors false;
bottomAir_to_heater
{
nFacesInCoarsestLevel 30;
featureAngle 10;
}
bottomAir_to_leftSolid
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
bottomAir_to_rightSolid
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
minX
{
nFacesInCoarsestLevel 10;
featureAngle 10;
}
minY
{
nFacesInCoarsestLevel 30;
featureAngle 10;
}
minZ
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
maxX
{
nFacesInCoarsestLevel 10;
featureAngle 10;
}
maxZ
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
// ************************************************************************* //

51
tutorials/heatTransfer/chtMultiRegionSimpleFoam/multiRegionHeaterRadiation/constant/topAir/viewFactorsDict
View File

@ -15,56 +15,5 @@ FoamFile
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
writeViewFactorMatrix true;
writeFacesAgglomeration true;
writePatchViewFactors false;
topAir_to_heater
{
nFacesInCoarsestLevel 24;
featureAngle 10;
}
topAir_to_leftSolid
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
topAir_to_rightSolid
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
minX
{
nFacesInCoarsestLevel 10;
featureAngle 10;
}
maxY
{
nFacesInCoarsestLevel 40;
featureAngle 10;
}
minZ
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
maxX
{
nFacesInCoarsestLevel 10;
featureAngle 10;
}
maxZ
{
nFacesInCoarsestLevel 20;
featureAngle 10;
}
// ************************************************************************* //