int main(int argc, char *argv[]) { LibUtilities::SessionReaderSharedPtr session; string vDriverModule; DriverSharedPtr drv; try { // Create session reader. session = LibUtilities::SessionReader::CreateInstance(argc, argv); // Create driver session->LoadSolverInfo("Driver", vDriverModule, "Standard"); drv = GetDriverFactory().CreateInstance(vDriverModule, session); // Execute driver drv->Execute(); // Finalise session session->Finalise(); } catch (const std::runtime_error& e) { return 1; } catch (const std::string& eStr) { cout << "Error: " << eStr << endl; } return 0; }
int main(int argc, char *argv[]) { string fname = std::string(argv[2]); int fdot = fname.find_last_of('.'); if (fdot != std::string::npos) { string ending = fname.substr(fdot); // If .chk or .fld we exchange the extension in the output file. // For all other files (e.g. .bse) we append the extension to avoid // conflicts. if (ending == ".chk" || ending == ".fld") { fname = fname.substr(0,fdot); } } fname = fname + ".txt"; int cnt; int id1, id2; int i, j, n, e, b; Array<OneD, NekDouble> auxArray; int nBndEdgePts, nBndEdges, nBndRegions; if (argc < 3) { fprintf(stderr, "Usage: ExtractSurface3DCFS meshfile fieldFile\n"); fprintf(stderr, "Extracts a surface from a 3D fld file" "(only for CompressibleFlowSolver and purely 3D .fld files)\n"); exit(1); } LibUtilities::SessionReaderSharedPtr vSession = LibUtilities::SessionReader::CreateInstance(3, argv); std::string m_ViscosityType; NekDouble m_gamma; NekDouble m_pInf; NekDouble m_rhoInf; NekDouble m_uInf; NekDouble m_vInf; NekDouble m_wInf; NekDouble m_gasConstant; NekDouble m_Twall; NekDouble m_mu; NekDouble m_thermalConductivity; int m_spacedim = 3; int nDimensions = m_spacedim; int phys_offset; // Get gamma parameter from session file. ASSERTL0(vSession->DefinesParameter("Gamma"), "Compressible flow sessions must define a Gamma parameter."); vSession->LoadParameter("Gamma", m_gamma, 1.4); // Get E0 parameter from session file. ASSERTL0(vSession->DefinesParameter("pInf"), "Compressible flow sessions must define a pInf parameter."); vSession->LoadParameter("pInf", m_pInf, 101325); // Get rhoInf parameter from session file. ASSERTL0(vSession->DefinesParameter("rhoInf"), "Compressible flow sessions must define a rhoInf parameter."); vSession->LoadParameter("rhoInf", m_rhoInf, 1.225); // Get uInf parameter from session file. ASSERTL0(vSession->DefinesParameter("uInf"), "Compressible flow sessions must define a uInf parameter."); vSession->LoadParameter("uInf", m_uInf, 0.1); // Get vInf parameter from session file. if (m_spacedim == 2 || m_spacedim == 3) { ASSERTL0(vSession->DefinesParameter("vInf"), "Compressible flow sessions must define a vInf parameter" "for 2D/3D problems."); vSession->LoadParameter("vInf", m_vInf, 0.0); } // Get wInf parameter from session file. if (m_spacedim == 3) { ASSERTL0(vSession->DefinesParameter("wInf"), "Compressible flow sessions must define a wInf parameter" "for 3D problems."); vSession->LoadParameter("wInf", m_wInf, 0.0); } vSession->LoadParameter ("GasConstant", m_gasConstant, 287.058); vSession->LoadParameter ("Twall", m_Twall, 300.15); vSession->LoadSolverInfo("ViscosityType", m_ViscosityType, "Constant"); vSession->LoadParameter ("mu", m_mu, 1.78e-05); vSession->LoadParameter ("thermalConductivity", m_thermalConductivity, 0.0257); //-------------------------------------------------------------------------- // Read in mesh from input file string meshfile(argv[1]); SpatialDomains::MeshGraphSharedPtr graphShPt = SpatialDomains::MeshGraph::Read(vSession); //-------------------------------------------------------------------------- //-------------------------------------------------------------------------- // Import field file string fieldFile(argv[2]); vector<LibUtilities::FieldDefinitionsSharedPtr> fieldDef; vector<vector<NekDouble> > fieldData; LibUtilities::Import(fieldFile, fieldDef, fieldData); //-------------------------------------------------------------------------- //-------------------------------------------------------------------------- // Set up Expansion information vector< vector<LibUtilities::PointsType> > pointsType; for (i = 0; i < fieldDef.size(); ++i) { vector<LibUtilities::PointsType> ptype; for (j = 0; j < 3; ++j) { ptype.push_back(LibUtilities::ePolyEvenlySpaced); } pointsType.push_back(ptype); } graphShPt->SetExpansions(fieldDef, pointsType); //-------------------------------------------------------------------------- //-------------------------------------------------------------------------- // Define Expansion int nfields = fieldDef[0]->m_fields.size(); Array<OneD, MultiRegions::ExpListSharedPtr> Exp(nfields); Array<OneD, MultiRegions::ExpListSharedPtr> pFields(nfields); for(i = 0; i < pFields.num_elements(); i++) { pFields[i] = MemoryManager<MultiRegions ::DisContField3D>::AllocateSharedPtr(vSession, graphShPt, vSession->GetVariable(i)); } MultiRegions::ExpList3DSharedPtr Exp3D; Exp3D = MemoryManager<MultiRegions::ExpList3D> ::AllocateSharedPtr(vSession, graphShPt); Exp[0] = Exp3D; for (i = 1; i < nfields; ++i) { Exp[i] = MemoryManager<MultiRegions::ExpList3D> ::AllocateSharedPtr(*Exp3D); } // Count of the point on the surface int nSurfacePts = 0; if (pFields[0]->GetBndCondExpansions().num_elements()) { nSurfacePts = 0; cnt = 0; nBndRegions = pFields[0]->GetBndCondExpansions().num_elements(); for (b = 0; b < nBndRegions; ++b) { nBndEdges = pFields[0]->GetBndCondExpansions()[b]->GetExpSize(); for (e = 0; e < nBndEdges; ++e) { nBndEdgePts = pFields[0]-> GetBndCondExpansions()[b]->GetExp(e)->GetTotPoints(); if (pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "WallViscous" || pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "WallAdiabatic" || pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "Wall") { nSurfacePts += nBndEdgePts; } } } } int nSolutionPts = pFields[0]->GetNpoints(); int nTracePts = pFields[0]->GetTrace()->GetTotPoints(); int nElements = pFields[0]->GetExpSize(); Array<OneD, NekDouble> tmp(nSolutionPts, 0.0); Array<OneD, NekDouble> x(nSolutionPts); Array<OneD, NekDouble> y(nSolutionPts); Array<OneD, NekDouble> z(nSolutionPts); Array<OneD, NekDouble> traceX(nTracePts); Array<OneD, NekDouble> traceY(nTracePts); Array<OneD, NekDouble> traceZ(nTracePts); Array<OneD, NekDouble> surfaceX(nSurfacePts); Array<OneD, NekDouble> surfaceY(nSurfacePts); Array<OneD, NekDouble> surfaceZ(nSurfacePts); pFields[0]->GetCoords(x, y, z); pFields[0]->ExtractTracePhys(x, traceX); pFields[0]->ExtractTracePhys(y, traceY); pFields[0]->ExtractTracePhys(z, traceZ); //-------------------------------------------------------------------------- //-------------------------------------------------------------------------- // Copy data from field file Array<OneD, Array<OneD, NekDouble> > uFields(nfields); Array<OneD, Array<OneD, NekDouble> > traceFields(nfields); Array<OneD, Array<OneD, NekDouble> > surfaceFields(nfields); // Extract the physical values of the solution at the boundaries for (j = 0; j < nfields; ++j) { uFields[j] = Array<OneD, NekDouble>(nSolutionPts, 0.0); traceFields[j] = Array<OneD, NekDouble>(nTracePts, 0.0); surfaceFields[j] = Array<OneD, NekDouble>(nSurfacePts, 0.0); for (i = 0; i < fieldData.size(); ++i) { Exp[j]->ExtractDataToCoeffs(fieldDef[i], fieldData[i], fieldDef[i]->m_fields[j], Exp[j]->UpdateCoeffs()); } Exp[j]->BwdTrans(Exp[j]->GetCoeffs(), Exp[j]->UpdatePhys()); Vmath::Vcopy(nSolutionPts, Exp[j]->GetPhys(), 1, uFields[j], 1); pFields[0]->ExtractTracePhys(uFields[j], traceFields[j]); } //Fields to add in the output file int nfieldsAdded = 34; Array<OneD, Array<OneD, NekDouble> > traceFieldsAdded(nfieldsAdded); Array<OneD, Array<OneD, NekDouble> > surfaceFieldsAdded(nfieldsAdded); for (j = 0; j < nfieldsAdded; ++j) { traceFieldsAdded[j] = Array<OneD, NekDouble>(nTracePts, 0.0); surfaceFieldsAdded[j] = Array<OneD, NekDouble>(nSurfacePts, 0.0); } /******** Evaluation of normals and tangents on the trace ***************** * nx -> traceFieldsAdded[0]; * ny -> traceFieldsAdded[1]; * nz -> traceFieldsAdded[2]; * bx -> traceFieldsAdded[3]; * by -> traceFieldsAdded[4]; * bz -> traceFieldsAdded[5]; * tx -> traceFieldsAdded[6]; * ty -> traceFieldsAdded[7]; * tz -> traceFieldsAdded[8]; ***************************************************************************/ Array<OneD, Array<OneD, NekDouble> > m_traceNormals (nDimensions); for(i = 0; i < nDimensions; ++i) { m_traceNormals[i] = Array<OneD, NekDouble> (nTracePts, 0.0); } pFields[0]->GetTrace()->GetNormals(m_traceNormals); Array<OneD, Array<OneD, NekDouble> > m_traceTangents (nDimensions); Array<OneD, Array<OneD, NekDouble> > m_traceBinormals (nDimensions); Array<OneD, Array<OneD, NekDouble> > h (nDimensions); Array<OneD, NekDouble > tmpNorm (nTracePts, 1.0); Array<OneD, NekDouble > NormH (nTracePts, 0.0); Array<OneD, NekDouble > tmpTrace (nTracePts, 0.0); for(i = 0; i < nDimensions; ++i) { m_traceTangents[i] = Array<OneD, NekDouble> (nTracePts, 0.0); m_traceBinormals[i] = Array<OneD, NekDouble> (nTracePts, 0.0); h[i] = Array<OneD, NekDouble> (nTracePts, 0.0); } // Normals // nx Vmath::Vcopy(nTracePts, &m_traceNormals[0][0], 1, &traceFieldsAdded[0][0], 1); // ny Vmath::Vcopy(nTracePts, &m_traceNormals[1][0], 1, &traceFieldsAdded[1][0], 1); // nz Vmath::Vcopy(nTracePts, &m_traceNormals[2][0], 1, &traceFieldsAdded[2][0], 1); // Tangents and Binormals // h1 Vmath::Vadd(nTracePts, &m_traceNormals[0][0], 1, &tmpNorm[0], 1, &h[0][0], 1); // h2 Vmath::Vcopy(nTracePts, &m_traceNormals[1][0], 1, &h[1][0], 1); // h3 Vmath::Vcopy(nTracePts, &m_traceNormals[2][0], 1, &h[2][0], 1); // Norm of h for (i = 0; i < m_spacedim; i++) { Vmath::Vvtvp (nTracePts, &h[i][0], 1, &h[i][0], 1, &NormH[0],1, &NormH[0],1); } //b1 Vmath::Vmul(nTracePts, &h[0][0], 1, &h[1][0], 1, &tmpTrace[0],1); Vmath::Vdiv(nTracePts, &tmpTrace[0],1, &NormH[0], 1, &tmpTrace[0],1); Vmath::Smul(nTracePts, -2.0, &tmpTrace[0], 1, &m_traceBinormals[0][0], 1); Vmath::Vcopy(nTracePts, &m_traceBinormals[0][0], 1, &traceFieldsAdded[3][0], 1); //b2 Vmath::Vmul(nTracePts, &h[1][0], 1, &h[1][0], 1, &tmpTrace[0],1); Vmath::Vdiv(nTracePts, &tmpTrace[0],1, &NormH[0], 1, &tmpTrace[0],1); Vmath::Smul(nTracePts, -2.0, &tmpTrace[0], 1, &tmpTrace[0], 1); Vmath::Vadd(nTracePts, &tmpTrace[0], 1, &tmpNorm[0], 1, &m_traceBinormals[1][0], 1); Vmath::Vcopy(nTracePts, &m_traceBinormals[1][0], 1, &traceFieldsAdded[4][0], 1); //b3 Vmath::Vmul(nTracePts, &h[1][0], 1, &h[2][0], 1, &tmpTrace[0],1); Vmath::Vdiv(nTracePts, &tmpTrace[0],1, &NormH[0], 1, &tmpTrace[0],1); Vmath::Smul(nTracePts, -2.0, &tmpTrace[0], 1, &m_traceBinormals[2][0], 1); Vmath::Vcopy(nTracePts, &m_traceBinormals[2][0], 1, &traceFieldsAdded[5][0], 1); //t1 Vmath::Vmul(nTracePts, &h[0][0], 1, &h[2][0], 1, &tmpTrace[0],1); Vmath::Vdiv(nTracePts, &tmpTrace[0],1, &NormH[0], 1, &tmpTrace[0],1); Vmath::Smul(nTracePts, -2.0, &tmpTrace[0], 1, &m_traceTangents[0][0], 1); Vmath::Vcopy(nTracePts, &m_traceTangents[0][0], 1, &traceFieldsAdded[6][0], 1); //t2 Vmath::Vcopy(nTracePts, &m_traceBinormals[2][0], 1, &m_traceTangents[1][0], 1); Vmath::Vcopy(nTracePts, &m_traceTangents[1][0], 1, &traceFieldsAdded[7][0], 1); //t3 Vmath::Vmul(nTracePts, &h[2][0], 1, &h[2][0], 1, &tmpTrace[0],1); Vmath::Vdiv(nTracePts, &tmpTrace[0],1, &NormH[0], 1, &tmpTrace[0],1); Vmath::Smul(nTracePts, -2.0, &tmpTrace[0], 1, &tmpTrace[0], 1); Vmath::Vadd(nTracePts, &tmpTrace[0], 1, &tmpNorm[0], 1, &m_traceTangents[2][0], 1); Vmath::Vcopy(nTracePts, &m_traceTangents[2][0], 1, &traceFieldsAdded[8][0], 1); /******** Evaluation of the pressure *************************************** * P = (E-1/2.*rho.*((rhou./rho).^2+(rhov./rho).^2))*(gamma - 1); * P -> traceFieldsAdded[9]; ***************************************************************************/ Array<OneD, NekDouble> pressure(nSolutionPts, 0.0); NekDouble gammaMinusOne = m_gamma - 1.0; for (i = 0; i < m_spacedim; i++) { Vmath::Vmul(nSolutionPts, &uFields[i + 1][0], 1, &uFields[i + 1][0], 1, &tmp[0],1); Vmath::Smul(nSolutionPts, 0.5, &tmp[0], 1, &tmp[0], 1); Vmath::Vadd(nSolutionPts, &pressure[0], 1, &tmp[0], 1, &pressure[0], 1); } Vmath::Vdiv(nSolutionPts, &pressure[0], 1, &uFields[0][0], 1, &pressure[0],1); Vmath::Vsub(nSolutionPts, &uFields[nfields - 1][0], 1, &pressure[0], 1, &pressure[0],1); Vmath::Smul(nSolutionPts, gammaMinusOne, &pressure[0], 1, &pressure[0], 1); // Extract trace pFields[0]->ExtractTracePhys(pressure, traceFieldsAdded[9]); /******** Evaluation of the temperature ************************************ * T = P/(R*rho); * T -> traceFieldsAdded[10]; ***************************************************************************/ Array<OneD, NekDouble> temperature(nSolutionPts, 0.0); Vmath::Vdiv(nSolutionPts, &pressure[0], 1, &uFields[0][0], 1, &temperature[0],1); NekDouble GasConstantInv = 1.0/m_gasConstant; Vmath::Smul(nSolutionPts, GasConstantInv, &temperature[0], 1, &temperature[0], 1); // Extract trace pFields[0]->ExtractTracePhys(temperature, traceFieldsAdded[10]); /*** Evaluation of the temperature gradient in the normal direction ******** * DT_n -> traceFieldsAdded[11] ***************************************************************************/ Array<OneD, Array<OneD, NekDouble> > Dtemperature(nDimensions); Array<OneD, Array<OneD, NekDouble> > traceDtemperature(nDimensions); for (i = 0; i < nDimensions; ++ i) { Dtemperature[i] = Array<OneD, NekDouble>(nSolutionPts, 0.0); traceDtemperature[i] = Array<OneD, NekDouble>(nTracePts, 0.0); } for (i = 0; i < nDimensions; ++ i) { for (n = 0; n < nElements; n++) { phys_offset = pFields[0]->GetPhys_Offset(n); pFields[i]->GetExp(n)->PhysDeriv( i, temperature + phys_offset, auxArray = Dtemperature[i] + phys_offset); } // Extract trace pFields[0]->ExtractTracePhys(Dtemperature[i], traceDtemperature[i]); } for(i = 0; i < nDimensions; ++i) { Vmath::Vmul(nTracePts, &m_traceNormals[i][0], 1, &traceDtemperature[i][0], 1, &tmp[0],1); Vmath::Vadd(nTracePts, &traceFieldsAdded[11][0], 1, &tmp[0], 1, &traceFieldsAdded[11][0], 1); } /*** Evaluation of the pressure gradient *********************************** * DP_t -> traceFieldsAdded[12] tangent direction * DP_b -> traceFieldsAdded[13] binormal direction * DP_x -> traceFieldsAdded[14] * DP_y -> traceFieldsAdded[15] * DP_z -> traceFieldsAdded[16] ***************************************************************************/ Array<OneD, Array<OneD, NekDouble> > Dpressure(nDimensions); Array<OneD, Array<OneD, NekDouble> > traceDpressure(nDimensions); for (i = 0; i < nDimensions; ++ i) { Dpressure[i] = Array<OneD, NekDouble>(nSolutionPts, 0.0); traceDpressure[i] = Array<OneD, NekDouble>(nTracePts, 0.0); } for (i = 0; i < nDimensions; ++ i) { for (n = 0; n < nElements; n++) { phys_offset = pFields[0]->GetPhys_Offset(n); pFields[i]->GetExp(n)->PhysDeriv( i, pressure + phys_offset, auxArray = Dpressure[i] + phys_offset); } // Extract trace pFields[0]->ExtractTracePhys(Dpressure[i], traceDpressure[i]); } // Dp_t for(i = 0; i < nDimensions; ++i) { Vmath::Vmul(nTracePts, &m_traceTangents[i][0], 1, &traceDpressure[i][0], 1, &tmp[0],1); Vmath::Vadd(nTracePts, &traceFieldsAdded[12][0], 1, &tmp[0], 1, &traceFieldsAdded[12][0], 1); } // Dp_b for(i = 0; i < nDimensions; ++i) { Vmath::Vmul(nTracePts, &m_traceBinormals[i][0], 1, &traceDpressure[i][0], 1, &tmp[0],1); Vmath::Vadd(nTracePts, &traceFieldsAdded[13][0], 1, &tmp[0], 1, &traceFieldsAdded[13][0], 1); } // Dp_x Vmath::Vcopy(nTracePts, &traceDpressure[0][0], 1, &traceFieldsAdded[14][0], 1); // Dp_y Vmath::Vcopy(nTracePts, &traceDpressure[1][0], 1, &traceFieldsAdded[15][0], 1); // Dp_z Vmath::Vcopy(nTracePts, &traceDpressure[2][0], 1, &traceFieldsAdded[16][0], 1); /** Evaluation of the velocity gradient in the cartesian directions * Du_x: traceFieldsAdded[17] * Du_y: traceFieldsAdded[18] * Du_z: traceFieldsAdded[19] * Dv_x: traceFieldsAdded[20] * Dv_y: traceFieldsAdded[21] * Dv_z: traceFieldsAdded[22] * Dw_x: traceFieldsAdded[23] * Dw_y: traceFieldsAdded[24] * Dw_z: traceFieldsAdded[25] **/ Array<OneD, Array<OneD, Array<OneD, NekDouble> > > Dvelocity(nDimensions); Array<OneD, Array<OneD, Array<OneD, NekDouble> > > traceDvelocity(nDimensions); Array<OneD, Array<OneD, NekDouble> > velocity(nDimensions); for (i = 0; i < nDimensions; ++ i) { Dvelocity[i] = Array<OneD, Array<OneD, NekDouble> >(nDimensions); traceDvelocity[i] = Array<OneD, Array<OneD, NekDouble> >(nDimensions); velocity[i] = Array<OneD, NekDouble>(nSolutionPts, 0.0); Vmath::Vdiv(nSolutionPts, uFields[i+1], 1, uFields[0], 1, velocity[i], 1); for (j = 0; j < nDimensions; ++j) { Dvelocity[i][j] = Array<OneD, NekDouble>(nSolutionPts, 0.0); traceDvelocity[i][j] = Array<OneD, NekDouble>(nTracePts, 0.0); } } for (i = 0; i < nDimensions; ++i) { for (j = 0; j < nDimensions; ++j) { for (n = 0; n < nElements; n++) { phys_offset = pFields[0]->GetPhys_Offset(n); pFields[i]->GetExp(n)->PhysDeriv( j, velocity[i] + phys_offset, auxArray = Dvelocity[i][j] + phys_offset); } // Extract trace pFields[0]->ExtractTracePhys(Dvelocity[i][j], traceDvelocity[i][j]); } } Vmath::Vcopy(nTracePts, &traceDvelocity[0][0][0], 1, &traceFieldsAdded[17][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[0][1][0], 1, &traceFieldsAdded[18][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[0][2][0], 1, &traceFieldsAdded[19][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[1][0][0], 1, &traceFieldsAdded[20][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[1][1][0], 1, &traceFieldsAdded[21][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[1][2][0], 1, &traceFieldsAdded[22][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[2][0][0], 1, &traceFieldsAdded[23][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[2][1][0], 1, &traceFieldsAdded[24][0], 1); Vmath::Vcopy(nTracePts, &traceDvelocity[2][2][0], 1, &traceFieldsAdded[25][0], 1); /*** Evaluation of shear stresses ****************************************** * tau_xx -> traceFieldsAdded[26] * tau_yy -> traceFieldsAdded[27] * tau_zz -> traceFieldsAdded[28] * tau_xy -> traceFieldsAdded[29] * tau_xz -> traceFieldsAdded[30] * tau_yz -> traceFieldsAdded[31] ***************************************************************************/ // Stokes hypotesis const NekDouble lambda = -2.0/3.0; // Auxiliary variables Array<OneD, NekDouble > mu (nSolutionPts, 0.0); Array<OneD, NekDouble > mu2 (nSolutionPts, 0.0); Array<OneD, NekDouble > divVel(nSolutionPts, 0.0); // Variable viscosity through the Sutherland's law if (m_ViscosityType == "Variable") { NekDouble mu_star = m_mu; NekDouble T_star = m_pInf / (m_rhoInf * m_gasConstant); NekDouble ratio; for (int i = 0; i < nSolutionPts; ++i) { ratio = temperature[i] / T_star; mu[i] = mu_star * ratio * sqrt(ratio) * (T_star + 110.0) / (temperature[i] + 110.0); } } else { Vmath::Fill(nSolutionPts, m_mu, &mu[0], 1); } // Computing diagonal terms of viscous stress tensor Array<OneD, Array<OneD, NekDouble> > temp(m_spacedim); Array<OneD, Array<OneD, NekDouble> > Sgg(m_spacedim); // mu2 = 2 * mu Vmath::Smul(nSolutionPts, 2.0, &mu[0], 1, &mu2[0], 1); // Velocity divergence Vmath::Vadd(nSolutionPts, &divVel[0], 1, &Dvelocity[0][0][0], 1, &divVel[0], 1); Vmath::Vadd(nSolutionPts, &divVel[0], 1, &Dvelocity[1][1][0], 1, &divVel[0], 1); // Velocity divergence scaled by lambda * mu Vmath::Smul(nSolutionPts, lambda, &divVel[0], 1, &divVel[0], 1); Vmath::Vmul(nSolutionPts, &mu[0], 1, &divVel[0], 1, &divVel[0], 1); // Diagonal terms of viscous stress tensor (Sxx, Syy) // Sjj = 2 * mu * du_j/dx_j - (2 / 3) * mu * sum_j(du_j/dx_j) for (j = 0; j < m_spacedim; ++j) { temp[j] = Array<OneD, NekDouble>(nSolutionPts, 0.0); Sgg[j] = Array<OneD, NekDouble>(nSolutionPts, 0.0); Vmath::Vmul(nSolutionPts, &mu2[0], 1, &Dvelocity[j][j][0], 1, &temp[j][0], 1); Vmath::Vadd(nSolutionPts, &temp[j][0], 1, &divVel[0], 1, &Sgg[j][0], 1); } // Extra diagonal terms of viscous stress tensor Array<OneD, NekDouble > Sxy(nSolutionPts, 0.0); Array<OneD, NekDouble > Sxz(nSolutionPts, 0.0); Array<OneD, NekDouble > Syz(nSolutionPts, 0.0); // Sxy = (du/dy + dv/dx) Vmath::Vadd(nSolutionPts, &Dvelocity[0][1][0], 1, &Dvelocity[1][0][0], 1, &Sxy[0], 1); // Sxz = (du/dz + dw/dx) Vmath::Vadd(nSolutionPts, &Dvelocity[0][2][0], 1, &Dvelocity[2][0][0], 1, &Sxz[0], 1); // Syz = (dv/dz + dw/dy) Vmath::Vadd(nSolutionPts, &Dvelocity[1][2][0], 1, &Dvelocity[2][1][0], 1, &Syz[0], 1); // Sxy = mu * (du/dy + dv/dx) Vmath::Vmul(nSolutionPts, &mu[0], 1, &Sxy[0], 1, &Sxy[0], 1); // Sxz = mu * (du/dy + dv/dx) Vmath::Vmul(nSolutionPts, &mu[0], 1, &Sxz[0], 1, &Sxz[0], 1); // Syz = mu * (du/dy + dv/dx) Vmath::Vmul(nSolutionPts, &mu[0], 1, &Syz[0], 1, &Syz[0], 1); pFields[0]->ExtractTracePhys(Sgg[0], traceFieldsAdded[26]); pFields[0]->ExtractTracePhys(Sgg[1], traceFieldsAdded[27]); pFields[0]->ExtractTracePhys(Sgg[2], traceFieldsAdded[28]); pFields[0]->ExtractTracePhys(Sxy, traceFieldsAdded[29]); pFields[0]->ExtractTracePhys(Sxz, traceFieldsAdded[30]); pFields[0]->ExtractTracePhys(Syz, traceFieldsAdded[31]); /*** Evaluation of dinamic viscosity *************************************** * mu -> traceFieldsAdded[32] ***************************************************************************/ pFields[0]->ExtractTracePhys(mu, traceFieldsAdded[32]); /*** Evaluation of Mach number ********************************************* * M -> traceFieldsAdded[33] ***************************************************************************/ NekDouble gamma = m_gamma; // Speed of sound Array<OneD, NekDouble> soundspeed(nSolutionPts, 0.0); Vmath::Vdiv (nSolutionPts, pressure, 1, uFields[0], 1, soundspeed, 1); Vmath::Smul (nSolutionPts, gamma, soundspeed, 1, soundspeed, 1); Vmath::Vsqrt(nSolutionPts, soundspeed, 1, soundspeed, 1); // Mach Array<OneD, NekDouble> mach(nSolutionPts, 0.0); for (int i = 0; i < m_spacedim; ++i) { Vmath::Vvtvp(nSolutionPts, uFields[i + 1], 1, uFields[i + 1], 1, mach, 1, mach, 1); } Vmath::Vdiv(nSolutionPts, mach, 1, uFields[0], 1, mach, 1); Vmath::Vdiv(nSolutionPts, mach, 1, uFields[0], 1, mach, 1); Vmath::Vsqrt(nSolutionPts, mach, 1, mach, 1); Vmath::Vdiv(nSolutionPts, mach, 1, soundspeed, 1, mach, 1); pFields[0]->ExtractTracePhys(mach, traceFieldsAdded[33]); /**************************************************************************/ // Extract coordinates if (pFields[0]->GetBndCondExpansions().num_elements()) { id1 = 0; cnt = 0; nBndRegions = pFields[0]->GetBndCondExpansions().num_elements(); for (b = 0; b < nBndRegions; ++b) { nBndEdges = pFields[0]->GetBndCondExpansions()[b]->GetExpSize(); for (e = 0; e < nBndEdges; ++e) { nBndEdgePts = pFields[0]-> GetBndCondExpansions()[b]->GetExp(e)->GetTotPoints(); id2 = pFields[0]->GetTrace()-> GetPhys_Offset(pFields[0]->GetTraceMap()-> GetBndCondTraceToGlobalTraceMap(cnt++)); if (pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "WallViscous" || pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "WallAdiabatic" || pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "Wall") { Vmath::Vcopy(nBndEdgePts, &traceX[id2], 1, &surfaceX[id1], 1); Vmath::Vcopy(nBndEdgePts, &traceY[id2], 1, &surfaceY[id1], 1); Vmath::Vcopy(nBndEdgePts, &traceZ[id2], 1, &surfaceZ[id1], 1); id1 += nBndEdgePts; } } } } // Extract fields if (pFields[0]->GetBndCondExpansions().num_elements()) { for (j = 0; j < nfields; ++j) { cout << "field " << j << endl; id1 = 0; cnt = 0; nBndRegions = pFields[j]->GetBndCondExpansions().num_elements(); for (b = 0; b < nBndRegions; ++b) { nBndEdges = pFields[j]->GetBndCondExpansions()[b]->GetExpSize(); for (e = 0; e < nBndEdges; ++e) { nBndEdgePts = pFields[j]-> GetBndCondExpansions()[b]->GetExp(e)->GetTotPoints(); id2 = pFields[j]->GetTrace()-> GetPhys_Offset(pFields[j]->GetTraceMap()-> GetBndCondTraceToGlobalTraceMap(cnt++)); if (pFields[j]->GetBndConditions()[b]-> GetUserDefined() == "WallViscous" || pFields[j]->GetBndConditions()[b]-> GetUserDefined() == "WallAdiabatic" || pFields[j]->GetBndConditions()[b]-> GetUserDefined() == "Wall") { Vmath::Vcopy(nBndEdgePts, &traceFields[j][id2], 1, &surfaceFields[j][id1], 1); id1 += nBndEdgePts; } } } } } // Extract fields added if (pFields[0]->GetBndCondExpansions().num_elements()) { for (j = 0; j < nfieldsAdded; ++j) { cout << "field added " << j << endl; id1 = 0; cnt = 0; nBndRegions = pFields[0]->GetBndCondExpansions().num_elements(); for (b = 0; b < nBndRegions; ++b) { nBndEdges = pFields[0]->GetBndCondExpansions()[b]->GetExpSize(); for (e = 0; e < nBndEdges; ++e) { nBndEdgePts = pFields[0]-> GetBndCondExpansions()[b]->GetExp(e)->GetTotPoints(); id2 = pFields[0]->GetTrace()-> GetPhys_Offset(pFields[0]->GetTraceMap()-> GetBndCondTraceToGlobalTraceMap(cnt++)); if (pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "WallViscous" || pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "WallAdiabatic" || pFields[0]->GetBndConditions()[b]-> GetUserDefined() == "Wall") { Vmath::Vcopy(nBndEdgePts, &traceFieldsAdded[j][id2], 1, &surfaceFieldsAdded[j][id1], 1); id1 += nBndEdgePts; } } } } } //========================================================================== //========================================================================== //========================================================================== // Print the surface coordinates and the surface solution in a .txt file ofstream outfile; outfile.open(fname.c_str()); outfile << "% x[m] " << " \t" << "y[m] " << " \t" << "z[m] " << " \t" << "nx[] " << " \t" << "ny[] " << " \t" << "nz[] " << " \t" << "bx[] " << " \t" << "by[] " << " \t" << "bz[] " << " \t" << "tx[] " << " \t" << "ty[] " << " \t" << "tz[] " << " \t" << "rho[kg/m^3] " << " \t" << "rhou[kg/(m^2 s)] " << " \t" << "rhov[kg/(m^2 s)] " << " \t" << "rhow[kg/(m^2 s)] " << " \t" << "E[Pa] " << " \t" << "p[Pa] " << " \t" << "T[k] " << " \t" << "dT/dn[k/m] " << " \t" << "dp/dT[Pa/m] " << " \t" << "dp/dB[Pa/m] " << " \t" << "dp/dx[Pa/m] " << " \t" << "dp/dy[Pa/m] " << " \t" << "dp/dz[Pa/m] " << " \t" << "du/dx[s^-1] " << " \t" << "du/dy[s^-1] " << " \t" << "du/dz[s^-1] " << " \t" << "dv/dx[s^-1] " << " \t" << "dv/dy[s^-1] " << " \t" << "dv/dz[s^-1] " << " \t" << "dw/dx[s^-1] " << " \t" << "dw/dy[s^-1] " << " \t" << "dw/dz[s^-1] " << " \t" << "tau_xx[Pa] " << " \t" << "tau_yy[Pa] " << " \t" << "tau_zz[Pa] " << " \t" << "tau_xy[Pa] " << " \t" << "tau_xz[Pa] " << " \t" << "tau_yz[Pa] " << " \t" << "mu[Pa s] " << " \t" << "M[] " << " \t" << endl; for (i = 0; i < nSurfacePts; ++i) { outfile << scientific << setw (17) << setprecision(16) << surfaceX[i] << " \t " << surfaceY[i] << " \t " << surfaceZ[i] << " \t " << surfaceFieldsAdded[0][i] << " \t " << surfaceFieldsAdded[1][i] << " \t " << surfaceFieldsAdded[2][i] << " \t " << surfaceFieldsAdded[3][i] << " \t " << surfaceFieldsAdded[4][i] << " \t " << surfaceFieldsAdded[5][i] << " \t " << surfaceFieldsAdded[6][i] << " \t " << surfaceFieldsAdded[7][i] << " \t " << surfaceFieldsAdded[8][i] << " \t " << surfaceFields[0][i] << " \t " << surfaceFields[1][i] << " \t " << surfaceFields[2][i] << " \t " << surfaceFields[3][i] << " \t " << surfaceFields[4][i] << " \t " << surfaceFieldsAdded[9][i] << " \t " << surfaceFieldsAdded[10][i] << " \t " << surfaceFieldsAdded[11][i] << " \t " << surfaceFieldsAdded[12][i] << " \t " << surfaceFieldsAdded[13][i] << " \t " << surfaceFieldsAdded[14][i] << " \t " << surfaceFieldsAdded[15][i] << " \t " << surfaceFieldsAdded[16][i] << " \t " << surfaceFieldsAdded[17][i] << " \t " << surfaceFieldsAdded[18][i] << " \t " << surfaceFieldsAdded[19][i] << " \t " << surfaceFieldsAdded[20][i] << " \t " << surfaceFieldsAdded[21][i] << " \t " << surfaceFieldsAdded[22][i] << " \t " << surfaceFieldsAdded[23][i] << " \t " << surfaceFieldsAdded[24][i] << " \t " << surfaceFieldsAdded[25][i] << " \t " << surfaceFieldsAdded[26][i] << " \t " << surfaceFieldsAdded[27][i] << " \t " << surfaceFieldsAdded[28][i] << " \t " << surfaceFieldsAdded[29][i] << " \t " << surfaceFieldsAdded[30][i] << " \t " << surfaceFieldsAdded[31][i] << " \t " << surfaceFieldsAdded[32][i] << " \t " << surfaceFieldsAdded[33][i] << " \t " << endl; } outfile << endl << endl; outfile.close(); return 0; }
int main(int argc, char *argv[]) { if(argc != 2) { fprintf(stderr,"Usage: ./Aliasing file.xml \n"); fprintf(stderr,"\t Method will read intiial conditions section of .xml file for input \n"); exit(1); } LibUtilities::SessionReaderSharedPtr session; string vDriverModule; DriverSharedPtr drv; try { // Create session reader. session = LibUtilities::SessionReader::CreateInstance(argc, argv); // Create driver session->LoadSolverInfo("Driver", vDriverModule, "Standard"); drv = GetDriverFactory().CreateInstance(vDriverModule, session); EquationSystemSharedPtr EqSys = drv->GetEqu()[0]; IncNavierStokesSharedPtr IncNav = EqSys->as<IncNavierStokes>(); IncNav->SetInitialConditions(0.0,false); Array<OneD, MultiRegions::ExpListSharedPtr> fields = IncNav->UpdateFields(); int i; int nConvectiveFields = IncNav->GetNConvectiveFields(); int nphys = fields[0]->GetTotPoints(); Array<OneD, Array<OneD, NekDouble> > VelFields(nConvectiveFields); Array<OneD, Array<OneD, NekDouble> > NonLinear(nConvectiveFields); Array<OneD, Array<OneD, NekDouble> > NonLinearDealiased(nConvectiveFields); for(i = 0; i < nConvectiveFields; ++i) { VelFields[i] = fields[i]->UpdatePhys(); NonLinear[i] = Array<OneD, NekDouble> (nphys); NonLinearDealiased[i] = Array<OneD, NekDouble> (nphys); } boost::shared_ptr<NavierStokesAdvection> A = boost::dynamic_pointer_cast<NavierStokesAdvection>(IncNav->GetAdvObject()); if (!A) { cout << "Must use non-linear Navier-Stokes advection" << endl; exit(-1); } // calculate non-linear terms without dealiasing A->SetSpecHPDealiasing(false); A->Advect(nConvectiveFields, fields, VelFields, VelFields, NonLinear, 0.0); // calculate non-linear terms with dealiasing A->SetSpecHPDealiasing(true); A->Advect(nConvectiveFields, fields, VelFields, VelFields, NonLinearDealiased, 0.0); // Evaulate Difference and put into fields; for(i = 0; i < nConvectiveFields; ++i) { Vmath::Vsub(nphys,NonLinearDealiased[i],1,NonLinear[i],1,NonLinear[i],1); fields[i]->FwdTrans_IterPerExp(NonLinear[i],fields[i]->UpdateCoeffs()); // Need to reset varibale name for output string name = "NL_Aliasing_"+session->GetVariable(i); session->SetVariable(i,name.c_str()); } // Reset session name for output file std::string outname = IncNav->GetSessionName(); outname += "_NonLinear_Aliasing"; IncNav->ResetSessionName(outname); IncNav->Output(); } catch (const std::runtime_error&) { return 1; } catch (const std::string& eStr) { cout << "Error: " << eStr << endl; } return 0; }
int main(int argc, char *argv[]) { SpatialDomains::PointGeomSharedPtr vPoint; MultiRegions::ExpListSharedPtr vExp; LibUtilities::SessionReaderSharedPtr vSession; std::string vCellModel; CellModelSharedPtr vCell; std::vector<StimulusSharedPtr> vStimulus; Array<OneD, Array<OneD, NekDouble> > vWsp(1); Array<OneD, Array<OneD, NekDouble> > vSol(1); NekDouble vDeltaT; NekDouble vTime; unsigned int nSteps; // Create a session reader to read pacing parameters vSession = LibUtilities::SessionReader::CreateInstance(argc, argv); try { // Construct a field consisting of a single vertex vPoint = MemoryManager<SpatialDomains::PointGeom> ::AllocateSharedPtr(3, 0, 0.0, 0.0, 0.0); vExp = MemoryManager<MultiRegions::ExpList0D> ::AllocateSharedPtr(vPoint); // Get cell model name and create it vSession->LoadSolverInfo("CELLMODEL", vCellModel, ""); ASSERTL0(vCellModel != "", "Cell Model not specified."); vCell = GetCellModelFactory().CreateInstance( vCellModel, vSession, vExp); vCell->Initialise(); // Load the stimuli vStimulus = Stimulus::LoadStimuli(vSession, vExp); // Set up solution arrays, workspace and read in parameters vSol[0] = Array<OneD, NekDouble>(1, 0.0); vWsp[0] = Array<OneD, NekDouble>(1, 0.0); vDeltaT = vSession->GetParameter("TimeStep"); vTime = 0.0; nSteps = vSession->GetParameter("NumSteps"); LibUtilities::EquationSharedPtr e = vSession->GetFunction("InitialConditions", "u"); vSol[0][0] = e->Evaluate(0.0, 0.0, 0.0, 0.0); // Time integrate cell model for (unsigned int i = 0; i < nSteps; ++i) { // Compute J_ion vCell->TimeIntegrate(vSol, vWsp, vTime); // Add stimuli J_stim for (unsigned int i = 0; i < vStimulus.size(); ++i) { vStimulus[i]->Update(vWsp, vTime); } // Time-step with forward Euler Vmath::Svtvp(1, vDeltaT, vWsp[0], 1, vSol[0], 1, vSol[0], 1); // Increment time vTime += vDeltaT; // Output current solution to stdout cout << vTime << " " << vSol[0][0] << endl; } for (unsigned int i = 0; i < vCell->GetNumCellVariables(); ++i) { cout << "# " << vCell->GetCellVarName(i) << " " << vCell->GetCellSolution(i)[0] << endl; } } catch (...) { cerr << "An error occured" << endl; } return 0; }