void PLCrackPrescribedDir::propagateInterfaces(EnrichmentDomain &ioEnrDom) { printf("Entering PLCrackPrescribedDir::propagateInterfaces().\n"); // Fetch crack tip data std::vector<TipInfo> tipInfo; ioEnrDom.giveTipInfos(tipInfo); int tipIndex = 1; FloatArray dir; double angleRad = mAngle*M_PI/180.0; dir.setValues(2, cos(angleRad), sin(angleRad)); dir.normalize(); std::vector<TipPropagation> tipPropagations; TipPropagation tipProp; tipProp.mTipIndex = tipIndex; tipProp.mPropagationDir = dir; tipProp.mPropagationLength = mIncrementLength; tipPropagations.push_back(tipProp); ioEnrDom.propagateTips(tipPropagations); }
void PLHoopStressCirc :: propagateInterfaces(Domain &iDomain, EnrichmentDomain &ioEnrDom) { // Fetch crack tip data TipInfo tipInfoStart, tipInfoEnd; ioEnrDom.giveTipInfos(tipInfoStart, tipInfoEnd); std :: vector< TipInfo >tipInfo = {tipInfoStart, tipInfoEnd}; SpatialLocalizer *localizer = iDomain.giveSpatialLocalizer(); for ( size_t tipIndex = 0; tipIndex < tipInfo.size(); tipIndex++ ) { // Construct circle points on an arc from -90 to 90 degrees double angle = -90.0 + mAngleInc; std :: vector< double >angles; while ( angle <= ( 90.0 - mAngleInc ) ) { angles.push_back(angle * M_PI / 180.0); angle += mAngleInc; } const FloatArray &xT = tipInfo [ tipIndex ].mGlobalCoord; const FloatArray &t = tipInfo [ tipIndex ].mTangDir; const FloatArray &n = tipInfo [ tipIndex ].mNormalDir; // It is meaningless to propagate a tip that is not inside any element Element *el = localizer->giveElementContainingPoint(tipInfo [ tipIndex ].mGlobalCoord); if ( el != NULL ) { std :: vector< FloatArray >circPoints; for ( size_t i = 0; i < angles.size(); i++ ) { FloatArray tangent(2); tangent.zero(); tangent.add(cos(angles [ i ]), t); tangent.add(sin(angles [ i ]), n); tangent.normalize(); FloatArray x(xT); x.add(mRadius, tangent); circPoints.push_back(x); } std :: vector< double >sigTTArray, sigRTArray; // Loop over circle points for ( size_t pointIndex = 0; pointIndex < circPoints.size(); pointIndex++ ) { FloatArray stressVec; if ( mUseRadialBasisFunc ) { // Interpolate stress with radial basis functions // Choose a cut-off length l: // take the distance between two nodes in the element containing the // crack tip multiplied by a constant factor. // ( This choice implies that we hope that the element has reasonable // aspect ratio.) const FloatArray &x1 = * ( el->giveDofManager(1)->giveCoordinates() ); const FloatArray &x2 = * ( el->giveDofManager(2)->giveCoordinates() ); const double l = 1.0 * x1.distance(x2); // Use the octree to get all elements that have // at least one Gauss point in a certain region around the tip. const double searchRadius = 3.0 * l; std :: set< int >elIndices; localizer->giveAllElementsWithIpWithinBox(elIndices, circPoints [ pointIndex ], searchRadius); // Loop over the elements and Gauss points obtained. // Evaluate the interpolation. FloatArray sumQiWiVi; double sumWiVi = 0.0; for ( int elIndex: elIndices ) { Element *gpEl = iDomain.giveElement(elIndex); IntegrationRule *iRule = gpEl->giveDefaultIntegrationRulePtr(); for ( GaussPoint *gp_i: *iRule ) { //////////////////////////////////////// // Compute global gp coordinates FloatArray N; FEInterpolation *interp = gpEl->giveInterpolation(); interp->evalN( N, * ( gp_i->giveCoordinates() ), FEIElementGeometryWrapper(gpEl) ); // Compute global coordinates of Gauss point FloatArray globalCoord(2); globalCoord.zero(); for ( int i = 1; i <= gpEl->giveNumberOfDofManagers(); i++ ) { DofManager *dMan = gpEl->giveDofManager(i); globalCoord.at(1) += N.at(i) * dMan->giveCoordinate(1); globalCoord.at(2) += N.at(i) * dMan->giveCoordinate(2); } //////////////////////////////////////// // Compute weight of kernel function FloatArray tipToGP; tipToGP.beDifferenceOf(globalCoord, xT); bool inFrontOfCrack = true; if ( tipToGP.dotProduct(t) < 0.0 ) { inFrontOfCrack = false; } double r = circPoints [ pointIndex ].distance(globalCoord); if ( r < l && inFrontOfCrack ) { double w = ( ( l - r ) / ( pow(2.0 * M_PI, 1.5) * pow(l, 3) ) ) * exp( -0.5 * pow(r, 2) / pow(l, 2) ); // Compute gp volume double V = gpEl->computeVolumeAround(gp_i); // Get stress StructuralMaterialStatus *ms = dynamic_cast< StructuralMaterialStatus * >( gp_i->giveMaterialStatus() ); if ( ms == NULL ) { OOFEM_ERROR("failed to fetch MaterialStatus."); } FloatArray stressVecGP = ms->giveStressVector(); if ( sumQiWiVi.giveSize() != stressVecGP.giveSize() ) { sumQiWiVi.resize( stressVecGP.giveSize() ); sumQiWiVi.zero(); } // Add to numerator sumQiWiVi.add(w * V, stressVecGP); // Add to denominator sumWiVi += w * V; } } } if ( fabs(sumWiVi) > 1.0e-12 ) { stressVec.beScaled(1.0 / sumWiVi, sumQiWiVi); } else { // Take stress from closest Gauss point int region = 1; bool useCZGP = false; GaussPoint &gp = * ( localizer->giveClosestIP(circPoints [ pointIndex ], region, useCZGP) ); // Compute stresses StructuralMaterialStatus *ms = dynamic_cast< StructuralMaterialStatus * >( gp.giveMaterialStatus() ); if ( ms == NULL ) { OOFEM_ERROR("failed to fetch MaterialStatus."); } stressVec = ms->giveStressVector(); } } else { // Take stress from closest Gauss point int region = 1; bool useCZGP = false; GaussPoint &gp = * ( localizer->giveClosestIP(circPoints [ pointIndex ], region, useCZGP) ); // Compute stresses StructuralMaterialStatus *ms = dynamic_cast< StructuralMaterialStatus * >( gp.giveMaterialStatus() ); if ( ms == NULL ) { OOFEM_ERROR("failed to fetch MaterialStatus."); } stressVec = ms->giveStressVector(); } FloatMatrix stress(2, 2); int shearPos = stressVec.giveSize(); stress.at(1, 1) = stressVec.at(1); stress.at(1, 2) = stressVec.at(shearPos); stress.at(2, 1) = stressVec.at(shearPos); stress.at(2, 2) = stressVec.at(2); // Rotation matrix FloatMatrix rot(2, 2); rot.at(1, 1) = cos(angles [ pointIndex ]); rot.at(1, 2) = -sin(angles [ pointIndex ]); rot.at(2, 1) = sin(angles [ pointIndex ]); rot.at(2, 2) = cos(angles [ pointIndex ]); FloatArray tRot, nRot; tRot.beProductOf(rot, t); nRot.beProductOf(rot, n); FloatMatrix rotTot(2, 2); rotTot.setColumn(tRot, 1); rotTot.setColumn(nRot, 2); FloatMatrix tmp, stressRot; tmp.beTProductOf(rotTot, stress); stressRot.beProductOf(tmp, rotTot); const double sigThetaTheta = stressRot.at(2, 2); sigTTArray.push_back(sigThetaTheta); const double sigRTheta = stressRot.at(1, 2); sigRTArray.push_back(sigRTheta); } ////////////////////////////// // Compute propagation angle // Find angles that fulfill sigRT = 0 const double stressTol = 1.0e-9; double maxSigTT = 0.0, maxAngle = 0.0; bool foundZeroLevel = false; for ( size_t segIndex = 0; segIndex < ( circPoints.size() - 1 ); segIndex++ ) { // If the shear stress sigRT changes sign over the segment if ( sigRTArray [ segIndex ] * sigRTArray [ segIndex + 1 ] < stressTol ) { // Compute location of zero level double xi = EnrichmentItem :: calcXiZeroLevel(sigRTArray [ segIndex ], sigRTArray [ segIndex + 1 ]); double theta = 0.5 * ( 1.0 - xi ) * angles [ segIndex ] + 0.5 * ( 1.0 + xi ) * angles [ segIndex + 1 ]; double sigThetaTheta = 0.5 * ( 1.0 - xi ) * sigTTArray [ segIndex ] + 0.5 * ( 1.0 + xi ) * sigTTArray [ segIndex + 1 ]; // printf("Found candidate: theta: %e sigThetaTheta: %e\n", theta, sigThetaTheta); if ( sigThetaTheta > maxSigTT ) { foundZeroLevel = true; maxSigTT = sigThetaTheta; maxAngle = theta; } } } if ( !foundZeroLevel ) { printf("No zero level was found.\n"); } if ( iDomain.giveXfemManager()->giveVtkDebug() ) { XFEMDebugTools :: WriteArrayToMatlab("sigTTvsAngle.m", angles, sigTTArray); XFEMDebugTools :: WriteArrayToMatlab("sigRTvsAngle.m", angles, sigRTArray); XFEMDebugTools :: WriteArrayToGnuplot("sigTTvsAngle.dat", angles, sigTTArray); XFEMDebugTools :: WriteArrayToGnuplot("sigRTvsAngle.dat", angles, sigRTArray); } // Compare with threshold if ( maxSigTT > mHoopStressThreshold && foundZeroLevel ) { // Rotation matrix FloatMatrix rot(2, 2); rot.at(1, 1) = cos(maxAngle); rot.at(1, 2) = -sin(maxAngle); rot.at(2, 1) = sin(maxAngle); rot.at(2, 2) = cos(maxAngle); FloatArray dir; dir.beProductOf(rot, tipInfo [ tipIndex ].mTangDir); // Fill up struct std :: vector< TipPropagation >tipPropagations; TipPropagation tipProp; tipProp.mTipIndex = tipIndex; tipProp.mPropagationDir = dir; tipProp.mPropagationLength = mIncrementLength; tipPropagations.push_back(tipProp); // Propagate ioEnrDom.propagateTips(tipPropagations); } } } }