void elasticitySolver::computeEffectiveStiffness(std::vector<double> stiff) { double st[6] = {0., 0., 0., 0., 0., 0.}; double volTot = 0.; for(std::size_t i = 0; i < elasticFields.size(); ++i) { double E = elasticFields[i]._e; double nu = elasticFields[i]._nu; SolverField<SVector3> Field(pAssembler, LagSpace); for(groupOfElements::elementContainer::const_iterator it = elasticFields[i].g->begin(); it != elasticFields[i].g->end(); ++it) { MElement *e = *it; double vol = e->getVolume() * e->getVolumeSign(); int nbVertex = e->getNumVertices(); std::vector<SVector3> val(nbVertex); double valx[256]; double valy[256]; double valz[256]; for(int k = 0; k < nbVertex; k++) { MVertex *v = e->getVertex(k); MPoint p(v); Field.f(&p, 0, 0, 0, val[k]); valx[k] = val[k](0); valy[k] = val[k](1); valz[k] = val[k](2); } double gradux[3]; double graduy[3]; double graduz[3]; SPoint3 center = e->barycenterUVW(); double u = center.x(), v = center.y(), w = center.z(); e->interpolateGrad(valx, u, v, w, gradux); e->interpolateGrad(valy, u, v, w, graduy); e->interpolateGrad(valz, u, v, w, graduz); double eps[6] = {gradux[0], graduy[1], graduz[2], 0.5 * (gradux[1] + graduy[0]), 0.5 * (gradux[2] + graduz[0]), 0.5 * (graduy[2] + graduz[1])}; double A = E / (1. + nu); double B = A * (nu / (1. - 2 * nu)); double trace = eps[0] + eps[1] + eps[2]; st[0] += (A * eps[0] + B * trace) * vol; st[1] += (A * eps[1] + B * trace) * vol; st[2] += (A * eps[2] + B * trace) * vol; st[3] += (A * eps[3]) * vol; st[4] += (A * eps[4]) * vol; st[5] += (A * eps[5]) * vol; volTot += vol; } } for(int i = 0; i < 6; i++) stiff[i] = st[i] / volTot; }
PView *elasticitySolver::buildStressesView(const std::string postFileName) { double sti[6] = {0., 0., 0., 0., 0., 0.}; double str[6] = {0., 0., 0., 0., 0., 0.}; double volTot = 0.; std::cout << "build stresses view" << std::endl; std::map<int, std::vector<double> > data; for(std::size_t i = 0; i < elasticFields.size(); ++i) { double E = elasticFields[i]._e; double nu = elasticFields[i]._nu; SolverField<SVector3> Field(pAssembler, LagSpace); for(groupOfElements::elementContainer::const_iterator it = elasticFields[i].g->begin(); it != elasticFields[i].g->end(); ++it) { MElement *e = *it; double vol = e->getVolume() * e->getVolumeSign(); int nbVertex = e->getNumVertices(); std::vector<SVector3> val(nbVertex); double valx[256]; double valy[256]; double valz[256]; for(int k = 0; k < nbVertex; k++) { MVertex *v = e->getVertex(k); MPoint p(v); Field.f(&p, 0, 0, 0, val[k]); valx[k] = val[k](0); valy[k] = val[k](1); valz[k] = val[k](2); } double gradux[3]; double graduy[3]; double graduz[3]; SPoint3 center = e->barycenterUVW(); double u = center.x(), v = center.y(), w = center.z(); e->interpolateGrad(valx, u, v, w, gradux); e->interpolateGrad(valy, u, v, w, graduy); e->interpolateGrad(valz, u, v, w, graduz); double eps[6] = {gradux[0], graduy[1], graduz[2], 0.5 * (gradux[1] + graduy[0]), 0.5 * (gradux[2] + graduz[0]), 0.5 * (graduy[2] + graduz[1])}; double A = E / (1. + nu); double B = A * (nu / (1. - 2 * nu)); double trace = eps[0] + eps[1] + eps[2]; double sxx = A * eps[0] + B * trace; double syy = A * eps[1] + B * trace; double szz = A * eps[2] + B * trace; double sxy = A * eps[3]; double sxz = A * eps[4]; double syz = A * eps[5]; std::vector<double> vec(9); vec[0] = sxx; vec[1] = sxy; vec[2] = sxz; vec[3] = sxy; vec[4] = syy; vec[5] = syz; vec[6] = sxz; vec[7] = syz; vec[8] = szz; data[e->getNum()] = vec; for(int k = 0; k < 6; k++) str[k] += eps[k] * vol; sti[0] += sxx * vol; sti[1] += syy * vol; sti[2] += szz * vol; sti[3] += sxy * vol; sti[4] += sxz * vol; sti[5] += syz * vol; volTot += vol; } } for(int i = 0; i < 6; i++) { str[i] = str[i] / volTot; sti[i] = sti[i] / volTot; } printf("effective stiffn = "); for(int i = 0; i < 6; i++) printf("%g ", sti[i]); printf("\n"); printf("effective strain = "); for(int i = 0; i < 6; i++) printf("%g ", str[i]); printf("\n"); PView *pv = new PView(postFileName, "ElementData", pModel, data, 0.0); return pv; }