コード例 #1
0
void TrPlaneStress2dXFEM :: computeGaussPoints()
{
    XfemManager *xMan = this->giveDomain()->giveXfemManager();

    for(int i = 1; i <= xMan->giveNumberOfEnrichmentItems(); i++)
    {
    	std::vector<FloatArray> intersecPoints;
    	EnrichmentItem *ei = xMan->giveEnrichmentItem(i);

        std::vector< int > intersecEdgeInd;
    	ei->computeIntersectionPoints(intersecPoints, intersecEdgeInd, this);
    	int numIntersecPoints = intersecPoints.size();

        if ( numIntersecPoints > 0 )
        {
            this->XfemElementInterface_updateIntegrationRule();
        } else
        {
            TrPlaneStress2d ::computeGaussPoints();
        }

    }

//	this->XfemElementInterface_updateIntegrationRule();
}
コード例 #2
0
ファイル: trplanstrssxfem.C プロジェクト: rreissnerr/oofem
void
TrPlaneStress2dXFEM :: giveDofManDofIDMask(int inode, IntArray &answer) const
{
    // Continuous part
    TrPlaneStress2d :: giveDofManDofIDMask(inode, answer);

    // Discontinuous part
    if( this->giveDomain()->hasXfemManager() ) {
        DofManager *dMan = giveDofManager(inode);
        XfemManager *xMan = giveDomain()->giveXfemManager();

        const std::vector<int> &nodeEiIndices = xMan->giveNodeEnrichmentItemIndices( dMan->giveGlobalNumber() );
        for ( size_t i = 0; i < nodeEiIndices.size(); i++ ) {
            EnrichmentItem *ei = xMan->giveEnrichmentItem(nodeEiIndices[i]);
            if ( ei->isDofManEnriched(* dMan) ) {
                IntArray eiDofIdArray;
                ei->computeEnrichedDofManDofIdArray(eiDofIdArray, *dMan);
                answer.followedBy(eiDofIdArray);
            }
        }
    }
}
コード例 #3
0
bool XfemStructuralElementInterface :: XfemElementInterface_updateIntegrationRule()
{
    const double tol2 = 1.0e-18;

    bool partitionSucceeded = false;


    if ( mpCZMat != NULL ) {
        mpCZIntegrationRules.clear();
        mCZEnrItemIndices.clear();
        mCZTouchingEnrItemIndices.clear();
    }

    XfemManager *xMan = this->element->giveDomain()->giveXfemManager();
    if ( xMan->isElementEnriched(element) ) {
        if ( mpCZMat == NULL && mCZMaterialNum > 0 ) {
            initializeCZMaterial();
        }


        MaterialMode matMode = element->giveMaterialMode();

        bool firstIntersection = true;

        std :: vector< std :: vector< FloatArray > >pointPartitions;
        mSubTri.clear();

        std :: vector< int >enrichingEIs;
        int elPlaceInArray = xMan->giveDomain()->giveElementPlaceInArray( element->giveGlobalNumber() );
        xMan->giveElementEnrichmentItemIndices(enrichingEIs, elPlaceInArray);


        for ( size_t p = 0; p < enrichingEIs.size(); p++ ) {
            // Index of current ei
            int eiIndex = enrichingEIs [ p ];

            // Indices of other ei interaction with this ei through intersection enrichment fronts.
            std :: vector< int >touchingEiIndices;
            giveIntersectionsTouchingCrack(touchingEiIndices, enrichingEIs, eiIndex, * xMan);

            if ( firstIntersection ) {
                // Get the points describing each subdivision of the element
                double startXi, endXi;
                bool intersection = false;
                this->XfemElementInterface_prepareNodesForDelaunay(pointPartitions, startXi, endXi, eiIndex, intersection);

                if ( intersection ) {
                    firstIntersection = false;

                    // Use XfemElementInterface_partitionElement to subdivide the element
                    for ( int i = 0; i < int ( pointPartitions.size() ); i++ ) {
                        // Triangulate the subdivisions
                        this->XfemElementInterface_partitionElement(mSubTri, pointPartitions [ i ]);
                    }


                    if ( mpCZMat != NULL ) {
                        Crack *crack = dynamic_cast< Crack * >( xMan->giveEnrichmentItem(eiIndex) );
                        if ( crack == NULL ) {
                            OOFEM_ERROR("Cohesive zones are only available for cracks.")
                        }

                        // We have xi_s and xi_e. Fetch sub polygon.
                        std :: vector< FloatArray >crackPolygon;
                        crack->giveSubPolygon(crackPolygon, startXi, endXi);

                        ///////////////////////////////////
                        // Add cohesive zone Gauss points
                        size_t numSeg = crackPolygon.size() - 1;

                        for ( size_t segIndex = 0; segIndex < numSeg; segIndex++ ) {
                            int czRuleNum = 1;
                            mpCZIntegrationRules.emplace_back( new GaussIntegrationRule(czRuleNum, element) );

                            // Add index of current ei
                            mCZEnrItemIndices.push_back(eiIndex);

                            // Add indices of other ei, that cause interaction through
                            // intersection enrichment fronts
                            mCZTouchingEnrItemIndices.push_back(touchingEiIndices);

                            // Compute crack normal
                            FloatArray crackTang;
                            crackTang.beDifferenceOf(crackPolygon [ segIndex + 1 ], crackPolygon [ segIndex ]);

                            if ( crackTang.computeSquaredNorm() > tol2 ) {
                                crackTang.normalize();
                            }

                            FloatArray crackNormal = {
                                -crackTang.at(2), crackTang.at(1)
                            };

                            mpCZIntegrationRules [ segIndex ]->SetUpPointsOn2DEmbeddedLine(mCSNumGaussPoints, matMode,
                                                                                           crackPolygon [ segIndex ], crackPolygon [ segIndex + 1 ]);

                            for ( GaussPoint *gp: *mpCZIntegrationRules [ segIndex ] ) {
                                double gw = gp->giveWeight();
                                double segLength = crackPolygon [ segIndex ].distance(crackPolygon [ segIndex + 1 ]);
                                gw *= 0.5 * segLength;
                                gp->setWeight(gw);

                                // Fetch material status and set normal
                                StructuralInterfaceMaterialStatus *ms = dynamic_cast< StructuralInterfaceMaterialStatus * >( mpCZMat->giveStatus(gp) );
                                if ( ms == NULL ) {
                                    OOFEM_ERROR("Failed to fetch material status.");
                                }

                                ms->letNormalBe(crackNormal);

                                // Give Gauss point reference to the enrichment item
                                // to simplify post processing.
                                crack->AppendCohesiveZoneGaussPoint(gp);
                            }
                        }
                    }



                    partitionSucceeded = true;
                }
            } // if(firstIntersection)
            else {
                // Loop over triangles
                std :: vector< Triangle >allTriCopy;
                for ( size_t triIndex = 0; triIndex < mSubTri.size(); triIndex++ ) {
                    // Call alternative version of XfemElementInterface_prepareNodesForDelaunay
                    std :: vector< std :: vector< FloatArray > >pointPartitionsTri;
                    double startXi, endXi;
                    bool intersection = false;
                    XfemElementInterface_prepareNodesForDelaunay(pointPartitionsTri, startXi, endXi, mSubTri [ triIndex ], eiIndex, intersection);

                    if ( intersection ) {
                        // Use XfemElementInterface_partitionElement to subdivide triangle j
                        for ( int i = 0; i < int ( pointPartitionsTri.size() ); i++ ) {
                            this->XfemElementInterface_partitionElement(allTriCopy, pointPartitionsTri [ i ]);
                        }


                        // Add cohesive zone Gauss points

                        if ( mpCZMat != NULL ) {
                            Crack *crack = dynamic_cast< Crack * >( xMan->giveEnrichmentItem(eiIndex) );
                            if ( crack == NULL ) {
                                OOFEM_ERROR("Cohesive zones are only available for cracks.")
                            }

                            // We have xi_s and xi_e. Fetch sub polygon.
                            std :: vector< FloatArray >crackPolygon;
                            crack->giveSubPolygon(crackPolygon, startXi, endXi);

                            int numSeg = crackPolygon.size() - 1;

                            for ( int segIndex = 0; segIndex < numSeg; segIndex++ ) {
                                int czRuleNum = 1;
                                mpCZIntegrationRules.emplace_back( new GaussIntegrationRule(czRuleNum, element) );
                                size_t newRuleInd = mpCZIntegrationRules.size() - 1;
                                mCZEnrItemIndices.push_back(eiIndex);

                                mCZTouchingEnrItemIndices.push_back(touchingEiIndices);

                                // Compute crack normal
                                FloatArray crackTang;
                                crackTang.beDifferenceOf(crackPolygon [ segIndex + 1 ], crackPolygon [ segIndex ]);

                                if ( crackTang.computeSquaredNorm() > tol2 ) {
                                    crackTang.normalize();
                                }

                                FloatArray crackNormal = {
                                    -crackTang.at(2), crackTang.at(1)
                                };

                                mpCZIntegrationRules [ newRuleInd ]->SetUpPointsOn2DEmbeddedLine(mCSNumGaussPoints, matMode,
                                                                                                 crackPolygon [ segIndex ], crackPolygon [ segIndex + 1 ]);

                                for ( GaussPoint *gp: *mpCZIntegrationRules [ newRuleInd ] ) {
                                    double gw = gp->giveWeight();
                                    double segLength = crackPolygon [ segIndex ].distance(crackPolygon [ segIndex + 1 ]);
                                    gw *= 0.5 * segLength;
                                    gp->setWeight(gw);

                                    // Fetch material status and set normal
                                    StructuralInterfaceMaterialStatus *ms = dynamic_cast< StructuralInterfaceMaterialStatus * >( mpCZMat->giveStatus(gp) );
                                    if ( ms == NULL ) {
                                        OOFEM_ERROR("Failed to fetch material status.");
                                    }

                                    ms->letNormalBe(crackNormal);

                                    // Give Gauss point reference to the enrichment item
                                    // to simplify post processing.
                                    crack->AppendCohesiveZoneGaussPoint(gp);
                                }
                            }
                        }
                    } else {
                        allTriCopy.push_back(mSubTri [ triIndex ]);
                    }
                }
コード例 #4
0
void GnuplotExportModule::doOutput(TimeStep *tStep, bool forcedOutput)
{
    if (!(testTimeStepOutput(tStep) || forcedOutput)) {
        return;
    }

    // Export the sum of reaction forces for each Dirichlet BC
    if(mExportReactionForces) {
        outputReactionForces(tStep);
    }

    Domain *domain = emodel->giveDomain(1);

    // Export output from boundary conditions
    if(mExportBoundaryConditions) {
        int numBC = domain->giveNumberOfBoundaryConditions();

        for(int i = 1; i <= numBC; i++) {

            PrescribedGradient *presGradBC = dynamic_cast<PrescribedGradient*>( domain->giveBc(i) );
            if(presGradBC != NULL) {
                outputBoundaryCondition(*presGradBC, tStep);
            }


            PrescribedGradientBCNeumann *presGradBCNeumann = dynamic_cast<PrescribedGradientBCNeumann*>( domain->giveBc(i) );
            if(presGradBCNeumann != NULL) {
                outputBoundaryCondition(*presGradBCNeumann, tStep);
            }

            PrescribedGradientBCWeak *presGradBCWeak = dynamic_cast<PrescribedGradientBCWeak*>( domain->giveBc(i) );
            if(presGradBCWeak != NULL) {
                outputBoundaryCondition(*presGradBCWeak, tStep);
            }

        }
    }

    mTimeHist.push_back( tStep->giveTargetTime() );

    if(mExportXFEM) {
        if(domain->hasXfemManager()) {
            XfemManager *xMan = domain->giveXfemManager();

            int numEI = xMan->giveNumberOfEnrichmentItems();

            std::vector< std::vector<FloatArray> > points;

            for(int i = 1; i <= numEI; i++) {
                EnrichmentItem *ei = xMan->giveEnrichmentItem(i);
                ei->callGnuplotExportModule(*this, tStep);

                GeometryBasedEI *geoEI = dynamic_cast<GeometryBasedEI*>(ei);
                if(geoEI != NULL) {
                    std::vector<FloatArray> eiPoints;
                    geoEI->giveSubPolygon(eiPoints, 0.0, 1.0);
                    points.push_back(eiPoints);
                }
            }

            outputXFEMGeometry(points);
        }
    }

    if(mExportMesh) {
        outputMesh(*domain);
    }

    if(mMonitorNodeIndex != -1) {
        DofManager *dMan = domain->giveDofManager(mMonitorNodeIndex);
        outputNodeDisp(*dMan, tStep);
    }
}
コード例 #5
0
ファイル: trplanstrssxfem.C プロジェクト: rreissnerr/oofem
void
TrPlaneStress2dXFEM :: giveCompositeExportData(std::vector< VTKPiece > &vtkPieces, IntArray &primaryVarsToExport, IntArray &internalVarsToExport, IntArray cellVarsToExport, TimeStep *tStep)
{
    vtkPieces.resize(1);

    const int numCells = mSubTri.size();

    if(numCells == 0) {
        // Enriched but uncut element
        // Visualize as a quad
        vtkPieces[0].setNumberOfCells(1);

        int numTotalNodes = 3;
        vtkPieces[0].setNumberOfNodes(numTotalNodes);

        // Node coordinates
        std :: vector< FloatArray >nodeCoords;
        for(int i = 1; i <= 3; i++) {
            FloatArray &x = *(giveDofManager(i)->giveCoordinates());
            nodeCoords.push_back(x);

            vtkPieces[0].setNodeCoords(i, x);
        }

        // Connectivity
        IntArray nodes1 = {1, 2, 3};
        vtkPieces[0].setConnectivity(1, nodes1);

        // Offset
        int offset = 3;
        vtkPieces[0].setOffset(1, offset);

        // Cell types
        vtkPieces[0].setCellType(1, 5); // Linear triangle




        // Export nodal variables from primary fields
        vtkPieces[0].setNumberOfPrimaryVarsToExport(primaryVarsToExport.giveSize(), numTotalNodes);

        for ( int fieldNum = 1; fieldNum <= primaryVarsToExport.giveSize(); fieldNum++ ) {
            UnknownType type = ( UnknownType ) primaryVarsToExport.at(fieldNum);

            for ( int nodeInd = 1; nodeInd <= numTotalNodes; nodeInd++ ) {

                if ( type == DisplacementVector ) { // compute displacement

                        FloatArray u = {0.0, 0.0, 0.0};

                        // Fetch global coordinates (in undeformed configuration)
                        const FloatArray &x = nodeCoords[nodeInd-1];

                        // Compute local coordinates
                        FloatArray locCoord;
                        computeLocalCoordinates(locCoord, x);

                        // Compute displacement in point
                        FloatMatrix NMatrix;
                        computeNmatrixAt(locCoord, NMatrix);
                        FloatArray solVec;
                        computeVectorOf(VM_Total, tStep, solVec);
                        FloatArray uTemp;
                        uTemp.beProductOf(NMatrix, solVec);

                        if(uTemp.giveSize() == 3) {
                            u = uTemp;
                        }
                        else {
                            u = {uTemp[0], uTemp[1], 0.0};
                        }

                        vtkPieces[0].setPrimaryVarInNode(fieldNum, nodeInd, u);
                } else {
                    printf("fieldNum: %d\n", fieldNum);
                    // TODO: Implement
//                    ZZNodalRecoveryMI_recoverValues(values, layer, ( InternalStateType ) 1, tStep); // does not work well - fix
//                    for ( int j = 1; j <= numCellNodes; j++ ) {
//                        vtkPiece.setPrimaryVarInNode(fieldNum, nodeNum, values [ j - 1 ]);
//                        nodeNum += 1;
//                    }
                }
            }
        }


        // Export nodal variables from internal fields
        vtkPieces[0].setNumberOfInternalVarsToExport(0, numTotalNodes);


        // Export cell variables
        vtkPieces[0].setNumberOfCellVarsToExport(cellVarsToExport.giveSize(), 1);
        for ( int i = 1; i <= cellVarsToExport.giveSize(); i++ ) {
            InternalStateType type = ( InternalStateType ) cellVarsToExport.at(i);
            FloatArray average;
            std :: unique_ptr< IntegrationRule > &iRule = integrationRulesArray [ 0 ];
            VTKXMLExportModule :: computeIPAverage(average, iRule.get(), this, type, tStep);

            FloatArray averageV9(9);
            averageV9.at(1) = average.at(1);
            averageV9.at(5) = average.at(2);
            averageV9.at(9) = average.at(3);
            averageV9.at(6) = averageV9.at(8) = average.at(4);
            averageV9.at(3) = averageV9.at(7) = average.at(5);
            averageV9.at(2) = averageV9.at(4) = average.at(6);

            vtkPieces[0].setCellVar( i, 1, averageV9 );
        }


        // Export of XFEM related quantities
        if ( domain->hasXfemManager() ) {
            XfemManager *xMan = domain->giveXfemManager();

            int nEnrIt = xMan->giveNumberOfEnrichmentItems();
            vtkPieces[0].setNumberOfInternalXFEMVarsToExport(xMan->vtkExportFields.giveSize(), nEnrIt, numTotalNodes);

            const int nDofMan = giveNumberOfDofManagers();


            for ( int field = 1; field <= xMan->vtkExportFields.giveSize(); field++ ) {
                XFEMStateType xfemstype = ( XFEMStateType ) xMan->vtkExportFields [ field - 1 ];

                for ( int enrItIndex = 1; enrItIndex <= nEnrIt; enrItIndex++ ) {
                    EnrichmentItem *ei = xMan->giveEnrichmentItem(enrItIndex);
                    for ( int nodeInd = 1; nodeInd <= numTotalNodes; nodeInd++ ) {

                        const FloatArray &x = nodeCoords[nodeInd-1];
                        FloatArray locCoord;
                        computeLocalCoordinates(locCoord, x);

                        FloatArray N;
                        FEInterpolation *interp = giveInterpolation();
                        interp->evalN( N, locCoord, FEIElementGeometryWrapper(this) );


                        if ( xfemstype == XFEMST_LevelSetPhi ) {
                            double levelSet = 0.0, levelSetInNode = 0.0;

                            for(int elNodeInd = 1; elNodeInd <= nDofMan; elNodeInd++) {
                                DofManager *dMan = giveDofManager(elNodeInd);
                                ei->evalLevelSetNormalInNode(levelSetInNode, dMan->giveGlobalNumber(), *(dMan->giveCoordinates()) );

                                levelSet += N.at(elNodeInd)*levelSetInNode;
                            }


                            FloatArray valueArray = {levelSet};
                            vtkPieces[0].setInternalXFEMVarInNode(field, enrItIndex, nodeInd, valueArray);

                        } else if ( xfemstype == XFEMST_LevelSetGamma ) {
                            double levelSet = 0.0, levelSetInNode = 0.0;

                            for(int elNodeInd = 1; elNodeInd <= nDofMan; elNodeInd++) {
                                DofManager *dMan = giveDofManager(elNodeInd);
                                ei->evalLevelSetTangInNode(levelSetInNode, dMan->giveGlobalNumber(), *(dMan->giveCoordinates()) );

                                levelSet += N.at(elNodeInd)*levelSetInNode;
                            }


                            FloatArray valueArray = {levelSet};
                            vtkPieces[0].setInternalXFEMVarInNode(field, enrItIndex, nodeInd, valueArray);

                        } else if ( xfemstype == XFEMST_NodeEnrMarker ) {
                            double nodeEnrMarker = 0.0, nodeEnrMarkerInNode = 0.0;

                            for(int elNodeInd = 1; elNodeInd <= nDofMan; elNodeInd++) {
                                DofManager *dMan = giveDofManager(elNodeInd);
                                ei->evalNodeEnrMarkerInNode(nodeEnrMarkerInNode, dMan->giveGlobalNumber() );

                                nodeEnrMarker += N.at(elNodeInd)*nodeEnrMarkerInNode;
                            }


                            FloatArray valueArray = {nodeEnrMarker};
                            vtkPieces[0].setInternalXFEMVarInNode(field, enrItIndex, nodeInd, valueArray);
                        }

                    }
                }
            }
        }

    }
    else {
        // Enriched and cut element

        XfemStructuralElementInterface::giveSubtriangulationCompositeExportData(vtkPieces, primaryVarsToExport, internalVarsToExport, cellVarsToExport, tStep);


    }

}