public static Results RunStaticExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); //ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new LUFactorization(); //newSolu.NonLinearScheme = new LoadControlledNewtonRaphson(); newSolu.ActivateNonLinearSolver = true; newSolu.NonLinearScheme.numberOfLoadSteps = 20; double[] externalForces = new double[78]; externalForces[76] = -1000000000.0; double[] reducedExternalFVector = BoundaryConditionsImposition.ReducedVector(externalForces, elementsAssembly.BoundedDOFsVector); newSolu.AssemblyData = elementsAssembly; newSolu.Solve(reducedExternalFVector); newSolu.PrintSolution(); return(new Results() { NonlinearSolution = new List <double[]>(), SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ShowToGUI.PlotInitialGeometry(elementsAssembly); double[] externalForces = nodalForcesVector; foreach (var dof in LoadedStructuralDOFs) { externalForces[dof - 1] = -4 * 100 * 1e3; } double[] reducedNodalForces = BoundaryConditionsImposition.ReducedVector(externalForces, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.LinearScheme = new LUFactorization(); structuralSolution.ActivateNonLinearSolver = true; //structuralSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); structuralSolution.NonLinearScheme.numberOfLoadSteps = 40; structuralSolution.NonLinearScheme.Tolerance = 1e-4; structuralSolution.Solve(reducedNodalForces); var solution = structuralSolution.GetSolution(); elementsAssembly.UpdateDisplacements(solution); ShowToGUI.PlotFinalGeometry(elementsAssembly); Dictionary <int, double[]> allstepssolutions = structuralSolution.GetAllStepsSolutions(); List <double[]> solutions = new List <double[]>(); structuralSolution.PrintSolution(); return(new Results() { NonlinearSolution = solutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { #region Structural IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); int countContactElements = elementsAssembly.CountElementsOfSameType(typeof(ContactNtN2D)); ShowToGUI.PlotInitialGeometry(elementsAssembly); structuralSolution.LinearScheme = new LUFactorization(); structuralSolution.NonLinearScheme.Tolerance = 1e-5; structuralSolution.ActivateNonLinearSolver = true; structuralSolution.NonLinearScheme.numberOfLoadSteps = 5; double[] externalForces3 = externalForcesStructuralVector; foreach (var dof in loadedStructuralDOFs) { externalForces3[dof - 1] = externalStructuralLoad; } double[] reducedExternalForces3 = BoundaryConditionsImposition.ReducedVector(externalForces3, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.Solve(reducedExternalForces3); double[] solvector3 = structuralSolution.GetSolution(); elementsAssembly.UpdateDisplacements(solvector3); ShowToGUI.PlotFinalGeometry(elementsAssembly); double[] fullSolVector3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solvector3, elementsAssembly.BoundedDOFsVector); Dictionary <int, INode> finalNodes = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVector3); double[] xFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item1; double[] yFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item2; Dictionary <int, double[]> allStepsSolutions = structuralSolution.GetAllStepsSolutions(); Dictionary <int, double[]> allStepsFullSolutions = new Dictionary <int, double[]>(); Dictionary <int, Dictionary <int, double[]> > allStepsContactForces = new Dictionary <int, Dictionary <int, double[]> >(); Dictionary <int, double[]> elementsInternalContactForcesVector; for (int i = 1; i <= allStepsSolutions.Count; i++) { elementsInternalContactForcesVector = new Dictionary <int, double[]>(); elementsAssembly.UpdateDisplacements(allStepsSolutions[i]); elementsInternalContactForcesVector[4] = elementsAssembly.ElementsAssembly[4].CreateInternalGlobalForcesVector(); allStepsContactForces[i] = elementsInternalContactForcesVector; string name = "ContactForce" + i.ToString() + ".dat"; VectorOperations.PrintVectorToFile(allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == 4).Value, @"C:\Users\Public\Documents\" + name); } for (int i = 0; i < allStepsSolutions.Count; i++) { allStepsFullSolutions.Add(i + 1, BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions.Single(m => m.Key == i + 1).Value, elementsAssembly.BoundedDOFsVector)); int j = i + 1; string name = "solution" + j.ToString() + ".dat"; VectorOperations.PrintVectorToFile(allStepsFullSolutions.Single(m => m.Key == i + 1).Value, @"C:\Users\Public\Documents\" + name); } List <double[]> structuralSolutions = new List <double[]>(); #endregion return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static void RunExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = false; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); MatrixOperations.PrintMatrix(globalStiffnessMatrix); }
public static Results RunExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new PCGSolver(); double[] externalForces = new double[] { 20000, 0, -25000 }; newSolu.AssemblyData = elementsAssembly; newSolu.Solve(externalForces); newSolu.PrintSolution(); return(new Results()); }
public static void RunExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new CholeskyFactorization(); newSolu.NonLinearScheme = new LoadControlledNewtonRaphson(); newSolu.ActivateNonLinearSolver = true; double[] externalForces = new double[] { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, -2000000, 0 }; newSolu.AssemblyData = elementsAssembly; newSolu.Solve(externalForces); newSolu.PrintSolution(); }
public static void RunStaticExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new BiCGSTABSolver(); newSolu.NonLinearScheme = new NewtonIterations(); newSolu.ActivateNonLinearSolver = true; newSolu.NonLinearScheme.numberOfLoadSteps = 15; double[] externalForces = new double[] { 0, 0, 0, 0, -4 * 2200000, 0, 0, 0, 0, 0, 0, 0 }; newSolu.AssemblyData = elementsAssembly; newSolu.Solve(externalForces); newSolu.PrintSolution(); }
public static Results RunStaticExample() { IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new PCGSolver(); newSolu.NonLinearScheme = new LoadControlledNewtonRaphson(); newSolu.ActivateNonLinearSolver = false; newSolu.NonLinearScheme.numberOfLoadSteps = 10; double[] externalForces = new double[] { 0, 0, 1e9, -1e9, 0, -1e9, 0, 0 }; newSolu.AssemblyData = elementsAssembly; newSolu.Solve(externalForces); newSolu.PrintSolution(); return(new Results()); }
public static Results RunStaticExample() { double T0 = 1.0; double kc = 1.0; IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new PCGSolver(); newSolu.ActivateNonLinearSolver = false; double[] externalForces = new double[] { 0.0, 0.0, 0.0, (T0 + Math.Sqrt(3.0) * T0) * kc / 6.0, (2.0 * T0 + Math.Sqrt(3.0) * T0 + T0) * kc / 6.0, (T0 + Math.Sqrt(3.0) * T0) * kc / 6.0 }; newSolu.AssemblyData = elementsAssembly; newSolu.Solve(externalForces); newSolu.PrintSolution(); double[] kati = newSolu.GetSolution(); return(new Results()); }
public static Results RunStaticExample() { #region Structural IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); //Gnuplot graphs ShowToGUI.PlotInitialGeometry(elementsAssembly); Dictionary <int, INode> initialNodes = elementsAssembly.Nodes; double[] initialXCoord = Assembly.NodalCoordinatesToVectors(initialNodes).Item1; double[] initialYCoord = Assembly.NodalCoordinatesToVectors(initialNodes).Item2; double[] Xvec1Initial = new double[totalNodes / 2]; double[] Yvec1Initial = new double[totalNodes / 2]; double[] Xvec2Initial = new double[totalNodes / 2]; double[] Yvec2Initial = new double[totalNodes / 2]; double[] Ζvec1Initial = Enumerable.Repeat(1.0, totalNodes / 2).ToArray(); double[] Ζvec2Initial = Enumerable.Repeat(1.0, totalNodes / 2).ToArray(); Array.Copy(initialXCoord, 0, Xvec1Initial, 0, totalNodes / 2); Array.Copy(initialYCoord, 0, Yvec1Initial, 0, totalNodes / 2); Array.Copy(initialXCoord, totalNodes / 2, Xvec2Initial, 0, totalNodes / 2); Array.Copy(initialYCoord, totalNodes / 2, Yvec2Initial, 0, totalNodes / 2); string pathForContour1 = @"C:\Users\Public\Documents\Total\1"; string pathForContour2 = @"C:\Users\Public\Documents\Total\2"; ExportToFile.CreateContourDataForMatlab(Xvec1Initial, Yvec1Initial, Ζvec1Initial, nodesInYCoor, nodesInXCoor, pathForContour1); ExportToFile.CreateContourDataForMatlab(Xvec2Initial, Yvec2Initial, Ζvec2Initial, nodesInYCoor, nodesInXCoor, pathForContour2); ///structuralSolution = new StaticSolver(); structuralSolution.LinearScheme = new PCGSolver(); //structuralSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); structuralSolution.NonLinearScheme.Tolerance = 1e-6; structuralSolution.ActivateNonLinearSolver = true; structuralSolution.NonLinearScheme.numberOfLoadSteps = 40; double[] externalForces3 = externalForcesStructuralVector; foreach (var dof in loadedStructuralDOFs) { externalForces3[dof - 1] = externalStructuralLoad; } double[] reducedExternalForces3 = BoundaryConditionsImposition.ReducedVector(externalForces3, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.Solve(reducedExternalForces3); double[] solvector3 = structuralSolution.GetSolution(); elementsAssembly.UpdateDisplacements(solvector3); ShowToGUI.PlotFinalGeometry(elementsAssembly); double[] fullSolVector3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solvector3, elementsAssembly.BoundedDOFsVector); Dictionary <int, INode> finalNodes = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVector3); double[] xFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item1; double[] yFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item2; Dictionary <int, double[]> allStepsSolutions = structuralSolution.GetAllStepsSolutions(); Dictionary <int, Dictionary <int, double[]> > allStepsContactForces = new Dictionary <int, Dictionary <int, double[]> >(); Dictionary <int, Dictionary <int, double> > allStepsProjectionPoints = new Dictionary <int, Dictionary <int, double> >(); Dictionary <int, double[]> elementsInternalContactForcesVector; Dictionary <int, double> projectionPointForEachElement; for (int i = 1; i <= allStepsSolutions.Count; i++) { elementsInternalContactForcesVector = new Dictionary <int, double[]>(); projectionPointForEachElement = new Dictionary <int, double>(); elementsAssembly.UpdateDisplacements(allStepsSolutions[i]); for (int j = totalElements + 1; j <= totalElements + totalContactElements - 1; j++) { elementsInternalContactForcesVector[j] = elementsAssembly.ElementsAssembly[j].CreateInternalGlobalForcesVector(); projectionPointForEachElement[j] = elementsAssembly.ElementsAssembly[j].ClosestPointProjection(); } allStepsContactForces[i] = elementsInternalContactForcesVector; allStepsProjectionPoints[i] = projectionPointForEachElement; } List <double[]> structuralSolutions = new List <double[]>(); ExportToFile.ExportMatlabInitialGeometry(elementsAssembly); #endregion #region Thermal List <double[]> thermalSolutions = new List <double[]>(); List <Dictionary <int, double> > contactContactivityForEachStep = new List <Dictionary <int, double> >(); for (int k = 1; k <= allStepsSolutions.Count; k++) { IAssembly elementsAssembly2 = CreateThermalAssembly(); for (int j = totalElements + 1; j <= totalElements + totalContactElements - 1; j++) { double[] contactForce = allStepsContactForces[k][j]; elementsAssembly2.ElementsProperties[j].ContactForceValue = -contactForce[5]; double projectionPoint = allStepsProjectionPoints[k][j]; elementsAssembly2.ElementsProperties[j].Dx1 = projectionPoint; } elementsAssembly2.CreateElementsAssembly(); elementsAssembly2.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix2 = elementsAssembly2.CreateTotalStiffnessMatrix(); ISolver thermalSolution = new StaticSolver(); thermalSolution.LinearScheme = new LUFactorization(); thermalSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); thermalSolution.NonLinearScheme.Tolerance = 1e-9; thermalSolution.ActivateNonLinearSolver = true; thermalSolution.NonLinearScheme.numberOfLoadSteps = 40; thermalSolution.AssemblyData = elementsAssembly2; double[] externalHeatFlux = externalHeatLoafVector; //externalHeatFlux[0] = externalHeatLoad; //externalHeatFlux[15] = externalHeatLoad; //externalHeatFlux[30] = externalHeatLoad; //externalHeatFlux[45] = externalHeatLoad; //externalHeatFlux[60] = externalHeatLoad; foreach (var dof in loadedThermalDOFs) { if ((dof == ThermalDof1 | dof == ThermalDof2)) { externalHeatFlux[dof - 1] = externalHeatLoad / 2; } else { externalHeatFlux[dof - 1] = externalHeatLoad; } } //foreach (var dof in loadedThermalDOFs) //{ // externalHeatFlux[dof - 1] = externalHeatLoad; //} //for (int i = 61; i <= 75; i++) //{ // externalHeatFlux[61] = externalHeatLoad; //} double[] reducedExternalHeatFlux = BoundaryConditionsImposition.ReducedVector(externalHeatFlux, thermalSolution.AssemblyData.BoundedDOFsVector); thermalSolution.Solve(reducedExternalHeatFlux); double[] tempSol = thermalSolution.GetSolution(); thermalSolutions.Add(tempSol); Dictionary <int, double> contactContactivity = AssemblyHelpMethods.RetrieveContactContactivity(thermalSolution.AssemblyData); contactContactivityForEachStep.Add(contactContactivity); } int[] thermalBoundCond = thermalBoundaryConditions; double[] fullStructuralSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[8], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[16], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[24], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[32], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[40], elementsAssembly.BoundedDOFsVector); double[] fullThermalSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[7], thermalBoundCond); double[] fullThermalSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[15], thermalBoundCond); double[] fullThermalSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[23], thermalBoundCond); double[] fullThermalSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[31], thermalBoundCond); double[] fullThermalSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[39], thermalBoundCond); double[] fullThermalSolfinal1 = new double[fullThermalSol1.Length + 1]; double[] fullThermalSolfinal2 = new double[fullThermalSol1.Length + 1]; double[] fullThermalSolfinal3 = new double[fullThermalSol1.Length + 1]; double[] fullThermalSolfinal4 = new double[fullThermalSol1.Length + 1]; double[] fullThermalSolfinal5 = new double[fullThermalSol1.Length + 1]; for (int runs = 0; runs < fullThermalSol1.Length; runs++) { fullThermalSolfinal1[runs] = fullThermalSol1[runs]; fullThermalSolfinal2[runs] = fullThermalSol2[runs]; fullThermalSolfinal3[runs] = fullThermalSol3[runs]; fullThermalSolfinal4[runs] = fullThermalSol4[runs]; fullThermalSolfinal5[runs] = fullThermalSol5[runs]; } double[] contactContactivityForLoadStep1 = contactContactivityForEachStep[3].Values.ToArray(); double[] contactContactivityForLoadStep2 = contactContactivityForEachStep[7].Values.ToArray(); double[] contactContactivityForLoadStep3 = contactContactivityForEachStep[11].Values.ToArray(); double[] contactContactivityForLoadStep4 = contactContactivityForEachStep[15].Values.ToArray(); double[] contactContactivityForLoadStep5 = contactContactivityForEachStep[19].Values.ToArray(); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol1), fullThermalSolfinal1, @"C:\Users\Public\Documents\Results1.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol2), fullThermalSolfinal2, @"C:\Users\Public\Documents\Results2.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol3), fullThermalSolfinal3, @"C:\Users\Public\Documents\Results3.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol4), fullThermalSolfinal4, @"C:\Users\Public\Documents\Results4.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol5), fullThermalSolfinal5, @"C:\Users\Public\Documents\Results5.dat"); VectorOperations.PrintVectorToFile(contactContactivityForLoadStep1, @"C:\Users\Public\Documents\contactivity1.dat"); VectorOperations.PrintVectorToFile(contactContactivityForLoadStep2, @"C:\Users\Public\Documents\contactivity2.dat"); VectorOperations.PrintVectorToFile(contactContactivityForLoadStep3, @"C:\Users\Public\Documents\contactivity3.dat"); VectorOperations.PrintVectorToFile(contactContactivityForLoadStep4, @"C:\Users\Public\Documents\contactivity4.dat"); VectorOperations.PrintVectorToFile(contactContactivityForLoadStep5, @"C:\Users\Public\Documents\contactivity5.dat"); structuralSolutions.Add(fullStructuralSol1); structuralSolutions.Add(fullStructuralSol2); structuralSolutions.Add(fullStructuralSol3); structuralSolutions.Add(fullStructuralSol4); structuralSolutions.Add(fullStructuralSol5); double[] Xvec1Final = new double[totalNodes / 2]; double[] Yvec1Final = new double[totalNodes / 2]; double[] Xvec2Final = new double[totalNodes / 2]; double[] Yvec2Final = new double[totalNodes / 2]; double[] Ζvec1Final = new double[totalNodes / 2]; double[] Ζvec2Final = new double[totalNodes / 2]; Array.Copy(xFinalNodalCoor, 0, Xvec1Final, 0, totalNodes / 2); Array.Copy(yFinalNodalCoor, 0, Yvec1Final, 0, totalNodes / 2); Array.Copy(fullThermalSol4, 0, Ζvec1Final, 0, totalNodes / 2); Array.Copy(xFinalNodalCoor, totalNodes / 2, Xvec2Final, 0, totalNodes / 2); Array.Copy(yFinalNodalCoor, totalNodes / 2, Yvec2Final, 0, totalNodes / 2); Array.Copy(fullThermalSol4, totalNodes / 2, Ζvec2Final, 0, totalNodes / 2); List <HeatMapData> plots2 = new List <HeatMapData>(); plots2.Add(new HeatMapData() { Xcoordinates = Xvec1Final, Ycoordinates = Yvec1Final, Temperatures = Ζvec1Final }); plots2.Add(new HeatMapData() { Xcoordinates = Xvec2Final, Ycoordinates = Yvec2Final, Temperatures = Ζvec2Final }); ShowToGUI.PlotHeatMap(plots2); string path = @"C:\Users\Public\Documents\Total\1final"; string path2 = @"C:\Users\Public\Documents\Total\2final"; ExportToFile.CreateContourDataForMatlab(Xvec1Final, Yvec1Final, Ζvec1Final, nodesInYCoor, nodesInXCoor, path); ExportToFile.CreateContourDataForMatlab(Xvec2Final, Yvec2Final, Ζvec2Final, nodesInYCoor, nodesInXCoor, path2); //ExportToFile.ExportGeometryDataWithTemperatures(finalNodes, fullTempSol); GnuPlot.Close(); while (true) { if (File.Exists(AppContext.BaseDirectory + "gnuplot.png") && new FileInfo(AppContext.BaseDirectory + "gnuplot.png").Length > 0) { break; } Thread.Sleep(100); } GnuPlot.KillProcess(); #endregion return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { #region Structural IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); //Gnuplot graphs ShowToGUI.PlotInitialGeometry(elementsAssembly); Dictionary <int, INode> initialNodes = elementsAssembly.Nodes; double[] initialXCoord = Assembly.NodalCoordinatesToVectors(initialNodes).Item1; double[] initialYCoord = Assembly.NodalCoordinatesToVectors(initialNodes).Item2; double[] Xvec1Initial = new double[totalNodes / 2]; double[] Yvec1Initial = new double[totalNodes / 2]; double[] Xvec2Initial = new double[totalNodes / 2]; double[] Yvec2Initial = new double[totalNodes / 2]; double[] Ζvec1Initial = Enumerable.Repeat(1.0, totalNodes / 2).ToArray(); double[] Ζvec2Initial = Enumerable.Repeat(1.0, totalNodes / 2).ToArray(); Array.Copy(initialXCoord, 0, Xvec1Initial, 0, totalNodes / 2); Array.Copy(initialYCoord, 0, Yvec1Initial, 0, totalNodes / 2); Array.Copy(initialXCoord, totalNodes / 2, Xvec2Initial, 0, totalNodes / 2); Array.Copy(initialYCoord, totalNodes / 2, Yvec2Initial, 0, totalNodes / 2); string pathForContour1 = @"C:\Users\Public\Documents\Total\1"; string pathForContour2 = @"C:\Users\Public\Documents\Total\2"; //ExportToFile.CreateContourDataForMatlab(Xvec1Initial, Yvec1Initial, Ζvec1Initial, nodesInYCoor, nodesInXCoor, pathForContour1); //ExportToFile.CreateContourDataForMatlab(Xvec2Initial, Yvec2Initial, Ζvec2Initial, nodesInYCoor, nodesInXCoor, pathForContour2); ///structuralSolution = new StaticSolver(); structuralSolution.LinearScheme = new PCGSolver(); //structuralSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); structuralSolution.NonLinearScheme.Tolerance = 1e-5; structuralSolution.ActivateNonLinearSolver = false; structuralSolution.NonLinearScheme.numberOfLoadSteps = 40; double[] externalForces3 = externalForcesStructuralVector; foreach (var dof in loadedStructuralDOFs) { externalForces3[dof - 1] = externalStructuralLoad; } double[] reducedExternalForces3 = BoundaryConditionsImposition.ReducedVector(externalForces3, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.Solve(reducedExternalForces3); double[] solvector3 = structuralSolution.GetSolution(); elementsAssembly.UpdateDisplacements(solvector3); ShowToGUI.PlotFinalGeometry(elementsAssembly); double[] fullSolVector3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solvector3, elementsAssembly.BoundedDOFsVector); double tempResult = fullSolVector3[fullSolVector3.Length - 1]; Dictionary <int, INode> finalNodes = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVector3); double[] xFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item1; double[] yFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item2; Dictionary <int, double[]> allStepsSolutions = structuralSolution.GetAllStepsSolutions(); Dictionary <int, Dictionary <int, double[]> > allStepsContactForces = new Dictionary <int, Dictionary <int, double[]> >(); Dictionary <int, double[]> elementsInternalContactForcesVector; for (int i = 1; i <= allStepsSolutions.Count; i++) { elementsInternalContactForcesVector = new Dictionary <int, double[]>(); elementsAssembly.UpdateDisplacements(allStepsSolutions[i]); for (int j = totalElements + 1; j <= totalElements; j++) { elementsInternalContactForcesVector[j] = elementsAssembly.ElementsAssembly[j].CreateInternalGlobalForcesVector(); } allStepsContactForces[i] = elementsInternalContactForcesVector; } List <double[]> structuralSolutions = new List <double[]>(); #endregion double[] fullStructuralSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[2], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[4], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[6], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[8], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[10], elementsAssembly.BoundedDOFsVector); structuralSolutions.Add(fullStructuralSol1); structuralSolutions.Add(fullStructuralSol2); structuralSolutions.Add(fullStructuralSol3); structuralSolutions.Add(fullStructuralSol4); structuralSolutions.Add(fullStructuralSol5); //ExportToFile.ExportGeometryDataWithTemperatures(finalNodes, fullTempSol); GnuPlot.Close(); while (true) { if (File.Exists(AppContext.BaseDirectory + "gnuplot.png") && new FileInfo(AppContext.BaseDirectory + "gnuplot.png").Length > 0) { break; } Thread.Sleep(100); } GnuPlot.KillProcess(); return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { #region Structural IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); //Gnuplot graphs ShowToGUI.PlotInitialGeometry(elementsAssembly); ExportToFile.ExportMatlabInitialGeometry(elementsAssembly); //ISolver structuralSolution = new StaticSolver(); structuralSolution.LinearScheme = new LUFactorization(); //structuralSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); structuralSolution.ActivateNonLinearSolver = true; structuralSolution.NonLinearScheme.numberOfLoadSteps = 10; //int[] BoundedDOFsVector2 = new int[] { 1, 2, 31, 32, 61, 62, 91, 92, 121, 122, 179, 180, 209, 210, 239, 240, 269, 270, 299, 300 }; double[] externalForces3 = externalForcesStructuralVector; foreach (var dof in loadedStructuralDOFs) { externalForces3[dof] = externalStructuralLoad; } //externalForces3[135] = externalStructuralLoad; //externalForces3[137] = externalStructuralLoad; //externalForces3[139] = externalStructuralLoad; //externalForces3[141] = externalStructuralLoad; //externalForces3[143] = externalStructuralLoad; //externalForces3[145] = externalStructuralLoad; //externalForces3[147] = externalStructuralLoad; //externalForces3[149] = externalStructuralLoad; double[] reducedExternalForces3 = BoundaryConditionsImposition.ReducedVector(externalForces3, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.Solve(reducedExternalForces3); double[] solvector3 = structuralSolution.GetSolution(); elementsAssembly.UpdateDisplacements(solvector3); //ShowToGUI.PlotFinalGeometry(elementsAssembly); double[] fullSolVector3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solvector3, elementsAssembly.BoundedDOFsVector); ExportToFile.ExportMatlabFinalGeometry(elementsAssembly, fullSolVector3); Dictionary <int, INode> finalNodes = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVector3); double[] xFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item1; double[] yFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item2; Dictionary <int, double[]> allStepsSolutions = structuralSolution.GetAllStepsSolutions(); Dictionary <int, Dictionary <int, double[]> > allStepsContactForces = new Dictionary <int, Dictionary <int, double[]> >(); Dictionary <int, double[]> elementsInternalContactForcesVector; for (int i = 1; i <= allStepsSolutions.Count; i++) { elementsInternalContactForcesVector = new Dictionary <int, double[]>(); elementsAssembly.UpdateDisplacements(allStepsSolutions[i]); for (int j = 113; j <= 120; j++) { elementsInternalContactForcesVector[j] = elementsAssembly.ElementsAssembly[j].CreateInternalGlobalForcesVector(); } allStepsContactForces[i] = elementsInternalContactForcesVector; } // double[] solVector2 = new double[280]; List <double[]> structuralSolutions = new List <double[]>(); // int[] BoundedDOFsVector = new int[] { 1, 2, 31, 32, 61, 62, 91, 92, 121, 122, 179, 180, 209, 210, 239, 240, 269, 270, 299, 300 }; // double[] externalForces2 = new double[300]; // for (int i = 1; i <= 5; i++) // { // structuralSolution.NonLinearScheme = new LoadControlledNewtonRaphson(solVector2); // externalForces2[135] = -10000.0 * i; // externalForces2[137] = -10000.0 * i; // externalForces2[139] = -10000.0 * i; // externalForces2[141] = -10000.0 * i; // externalForces2[143] = -10000.0 * i; // externalForces2[145] = -10000.0 * i; // externalForces2[147] = -10000.0 * i; // externalForces2[149] = -10000.0 * i; // double[] reducedExternalForces2 = BoundaryConditionsImposition.ReducedVector(externalForces2, BoundedDOFsVector); // structuralSolution.AssemblyData = elementsAssembly; // structuralSolution.Solve(reducedExternalForces2); // solVector2 = structuralSolution.GetSolution(); // structuralSolutions.Add(solVector2); // } // Dictionary<int, double[]> intForces = structuralSolution.GetInternalForces(); // Dictionary<int, double[]> elementInternalForces = elementsAssembly.GetElementsInternalForces(structuralSolutions[0]); // List<string> elementTypes = elementsAssembly.GetElementsType(); // double[] completeFinalSolutionVector = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solVector2, BoundedDOFsVector); // Dictionary<int, INode> finalNodesList = new Dictionary<int, INode>(); // finalNodesList = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, completeFinalSolutionVector); #endregion #region Thermal List <double[]> thermalSolutions = new List <double[]>(); for (int k = 1; k <= allStepsSolutions.Count; k++) { IAssembly elementsAssembly2 = CreateThermalAssembly(); for (int j = 113; j < 120; j++) { double[] contactForce = allStepsContactForces[k][j]; elementsAssembly2.ElementsProperties[j].ContactForceValue = VectorOperations.VectorNorm2(new double[] { contactForce[2], contactForce[3] }); } elementsAssembly2.CreateElementsAssembly(); elementsAssembly2.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix2 = elementsAssembly2.CreateTotalStiffnessMatrix(); ISolver thermalSolution = new StaticSolver(); thermalSolution.LinearScheme = new LUFactorization(); thermalSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); thermalSolution.ActivateNonLinearSolver = true; thermalSolution.NonLinearScheme.numberOfLoadSteps = 10; thermalSolution.AssemblyData = elementsAssembly2; double[] externalHeatFlux = externalHeatLoafVector; //externalHeatFlux[0] = externalHeatLoad; //externalHeatFlux[15] = externalHeatLoad; //externalHeatFlux[30] = externalHeatLoad; //externalHeatFlux[45] = externalHeatLoad; //externalHeatFlux[60] = externalHeatLoad; foreach (var dof in loadedThermalDOFs) { externalHeatFlux[dof] = externalHeatLoad; } //for (int i = 61; i <= 75; i++) //{ // externalHeatFlux[61] = externalHeatLoad; //} double[] reducedExternalHeatFlux = BoundaryConditionsImposition.ReducedVector(externalHeatFlux, thermalSolution.AssemblyData.BoundedDOFsVector); thermalSolution.Solve(reducedExternalHeatFlux); double[] tempSol = thermalSolution.GetSolution(); thermalSolutions.Add(tempSol); } int[] thermalBoundCond = thermalBoundaryConditions; double[] fullStructuralSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[2], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[4], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[6], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[8], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[10], elementsAssembly.BoundedDOFsVector); double[] fullThermalSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[1], thermalBoundCond); double[] fullThermalSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[3], thermalBoundCond); double[] fullThermalSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[5], thermalBoundCond); double[] fullThermalSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[7], thermalBoundCond); double[] fullThermalSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[9], thermalBoundCond); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol1), fullThermalSol1, @"C:\Users\Public\Documents\Results1.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol2), fullThermalSol2, @"C:\Users\Public\Documents\Results2.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol3), fullThermalSol3, @"C:\Users\Public\Documents\Results3.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol4), fullThermalSol4, @"C:\Users\Public\Documents\Results4.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol5), fullThermalSol5, @"C:\Users\Public\Documents\Results5.dat"); //double[] temperatures = new double[135]; //int[] BoundedDOFsVectorForHeat = new int[] { 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165 }; //for (int i = 1; i <= 5; i++) //{ // thermalSolution.NonLinearScheme = new LoadControlledNewtonRaphson(temperatures); // double[] externalHeatFlux = new double[150]; // double[] reducedExternalHeatFlux = BoundaryConditionsImposition.ReducedVector(externalHeatFlux, BoundedDOFsVectorForHeat); // thermalSolution.AssemblyData = elementsAssembly2; // thermalSolution.Solve(reducedExternalHeatFlux); // temperatures = thermalSolution.GetSolution(); // thermalSolutions.Add(temperatures); //} //List<double> X = new List<double>(); //List<double> Y = new List<double>(); //double[] fullTempSol = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(tempSol, thermalSolution.AssemblyData.BoundedDOFsVector); //double[] Z = fullTempSol;//thermalSolutions[4]; //foreach (var node in elementsAssembly2.Nodes) //{ // X.Add(node.Value.XCoordinate); // Y.Add(node.Value.YCoordinate); //} //double[] Xvec = X.ToArray(); //double[] Yvec = Y.ToArray(); //double[] Xvec1 = new double[75]; //double[] Yvec1 = new double[75]; //double[] Zvec1 = new double[75]; //double[] Xvec2 = new double[75]; //double[] Yvec2 = new double[75]; //double[] Zvec2 = new double[75]; //Array.Copy(Xvec, 75, Xvec2, 0, 75); //Array.Copy(Yvec, 75, Yvec2, 0, 75); //Array.Copy(Z, 75, Zvec2, 0, 75); //Array.Copy(Xvec, 0, Xvec1, 0, 75); //Array.Copy(Yvec, 0, Yvec1, 0, 75); //Array.Copy(Z, 0, Zvec1, 0, 75); //GnuPlot.Set("terminal png size 500, 300"); //GnuPlot.Set("output 'gnuplot.png'"); //GnuPlot.HoldOn(); //GnuPlot.Set("cbrange[0:20.0]"); //GnuPlot.Set("palette defined(0 \"blue\", 1 \"red\")"); //GnuPlot.Set("pm3d"); //GnuPlot.Set("dgrid3d"); //GnuPlot.Set("view map"); //GnuPlot.SPlot(Xvec1, Yvec1, Zvec1); //GnuPlot.SPlot(Xvec2, Yvec2, Zvec2); //GnuPlot.Set("output"); //List<HeatMapData> plots = new List<HeatMapData>(); //plots.Add(new HeatMapData() { Xcoordinates = Xvec1, Ycoordinates = Yvec1, Temperatures = Zvec1 }); //plots.Add(new HeatMapData() { Xcoordinates = Xvec2, Ycoordinates = Yvec2, Temperatures = Zvec2 }); ////ShowToGUI.PlotHeatMap(plots); double[] Xvec1Final = new double[75]; double[] Yvec1Final = new double[75]; double[] Xvec2Final = new double[75]; double[] Yvec2Final = new double[75]; double[] Ζvec1Final = new double[75]; double[] Ζvec2Final = new double[75]; Array.Copy(xFinalNodalCoor, 0, Xvec1Final, 0, 75); Array.Copy(yFinalNodalCoor, 0, Yvec1Final, 0, 75); Array.Copy(fullThermalSol4, 0, Ζvec1Final, 0, 75); Array.Copy(xFinalNodalCoor, 75, Xvec2Final, 0, 75); Array.Copy(yFinalNodalCoor, 75, Yvec2Final, 0, 75); Array.Copy(fullThermalSol4, 75, Ζvec2Final, 0, 75); List <HeatMapData> plots2 = new List <HeatMapData>(); plots2.Add(new HeatMapData() { Xcoordinates = Xvec1Final, Ycoordinates = Yvec1Final, Temperatures = Ζvec1Final }); plots2.Add(new HeatMapData() { Xcoordinates = Xvec2Final, Ycoordinates = Yvec2Final, Temperatures = Ζvec2Final }); //GnuPlot.HoldOn(); //GnuPlot.Set("pm3d"); //GnuPlot.Set("dgrid3d"); //GnuPlot.Set("view map"); //GnuPlot.SPlot(new double[] { -1.0, 2.0, 1.0, -1.0}, new double[] { 1.0, 2.0, -1.0, 1.0 }, new double[] { 2, 1, 3, 2 }); ////GnuPlot.SPlot(new double[] { -1.0, 1.0, 3.0 }, new double[] { 2.0, 2.0, -1.0 }, new double[] { 5, 4, 9 }); ////GnuPlot.Plot(Xvec2Final, Yvec2Final); ShowToGUI.PlotHeatMap(plots2); string path = @"C:\Users\Public\Documents\Total\1final"; string path2 = @"C:\Users\Public\Documents\Total\2final"; ExportToFile.CreateContourDataForMatlab(Xvec1Final, Yvec1Final, Ζvec1Final, 5, 15, path); ExportToFile.CreateContourDataForMatlab(Xvec2Final, Yvec2Final, Ζvec2Final, 5, 15, path2); //ExportToFile.ExportGeometryDataWithTemperatures(finalNodes, fullTempSol); GnuPlot.Close(); while (true) { if (File.Exists(AppContext.BaseDirectory + "gnuplot.png") && new FileInfo(AppContext.BaseDirectory + "gnuplot.png").Length > 0) { break; } Thread.Sleep(100); } GnuPlot.KillProcess(); #endregion structuralSolutions.Add(fullStructuralSol1); structuralSolutions.Add(fullStructuralSol2); structuralSolutions.Add(fullStructuralSol3); structuralSolutions.Add(fullStructuralSol4); structuralSolutions.Add(fullStructuralSol5); diagramData.ShowResults(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { #region Structural IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); int countContactElements = elementsAssembly.CountElementsOfSameType(typeof(ContactStS2D)); ShowToGUI.PlotInitialGeometry(elementsAssembly); structuralSolution.LinearScheme = new LUFactorization(); structuralSolution.NonLinearScheme.Tolerance = 1e-5; structuralSolution.ActivateNonLinearSolver = true; structuralSolution.NonLinearScheme.numberOfLoadSteps = 30; double[] externalForces3 = externalForcesStructuralVector; foreach (var dof in loadedStructuralDOFs) { externalForces3[dof - 1] = externalStructuralLoad; } double[] reducedExternalForces3 = BoundaryConditionsImposition.ReducedVector(externalForces3, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.Solve(reducedExternalForces3); double[] solvector3 = structuralSolution.GetSolution(); Dictionary <int, double[]> allStepsSolutions = structuralSolution.GetAllStepsSolutions(); Dictionary <int, List <double[]> > gPointsStress = new Dictionary <int, List <double[]> >(); Dictionary <int, List <double[]> > gPointsStrain = new Dictionary <int, List <double[]> >(); Dictionary <int, List <double[]> > gPoints = new Dictionary <int, List <double[]> >(); Dictionary <int, List <double[]> > nodalStress = new Dictionary <int, List <double[]> >(); Dictionary <int, List <double[]> > nodalStrain = new Dictionary <int, List <double[]> >(); for (int i = 1; i <= allStepsSolutions.Count; i++) { string name = "NodalCoordinates" + i.ToString() + ".dat"; ExportToFile.ExportUpdatedNodalCoordinates(elementsAssembly, BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions.Single(m => m.Key == i).Value, elementsAssembly.BoundedDOFsVector), name); gPointsStress = elementsAssembly.GetElementsStresses(allStepsSolutions[i]); gPointsStrain = elementsAssembly.GetElementsStains(allStepsSolutions[i]); gPoints = elementsAssembly.GetElementsGaussPoints(allStepsSolutions[i]); nodalStress = elementsAssembly.GetElementsNodesStresses(allStepsSolutions[i]); nodalStrain = elementsAssembly.GetElementsNodesStains(allStepsSolutions[i]); string name1 = "GPointsStress" + i.ToString() + ".dat"; string name2 = "GPointsStrain" + i.ToString() + ".dat"; string name3 = "GPointsCoordinates" + i.ToString() + ".dat"; string name4 = "NodalStress" + i.ToString() + ".dat"; string name5 = "NodalStrain" + i.ToString() + ".dat"; VectorOperations.PrintDictionaryofListsofVectorsToFile(gPointsStress, @"C:\Users\Public\Documents\" + name1); VectorOperations.PrintDictionaryofListsofVectorsToFile(gPointsStrain, @"C:\Users\Public\Documents\" + name2); VectorOperations.PrintDictionaryofListsofVectorsToFile(gPoints, @"C:\Users\Public\Documents\" + name3); VectorOperations.PrintDictionaryofListsofVectorsToFile(nodalStress, @"C:\Users\Public\Documents\" + name4); VectorOperations.PrintDictionaryofListsofVectorsToFile(nodalStrain, @"C:\Users\Public\Documents\" + name5); } elementsAssembly.UpdateDisplacements(solvector3); ShowToGUI.PlotFinalGeometry(elementsAssembly); double[] fullSolVector3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solvector3, elementsAssembly.BoundedDOFsVector); Dictionary <int, INode> finalNodes = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVector3); double[] xFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item1; double[] yFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item2; Dictionary <int, double[]> allStepsFullSolutions = new Dictionary <int, double[]>(); Dictionary <int, Dictionary <int, double[]> > allStepsContactForces = new Dictionary <int, Dictionary <int, double[]> >(); Dictionary <int, double[]> elementsInternalContactForcesVector; for (int i = 1; i <= allStepsSolutions.Count; i++) { elementsInternalContactForcesVector = new Dictionary <int, double[]>(); elementsAssembly.UpdateDisplacements(allStepsSolutions[i]); for (int j = 1; j <= contactElements; j++) { elementsInternalContactForcesVector[elementsNumber + j] = elementsAssembly.ElementsAssembly[elementsNumber + j].CreateInternalGlobalForcesVector(); } allStepsContactForces[i] = elementsInternalContactForcesVector; string name = "ContactForces" + i.ToString() + ".dat"; double[] Vector = new double[contactElements * 12]; int count = 0; for (int j = 1; j <= contactElements; j++) { Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[0]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[1]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[2]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[3]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[4]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[5]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[6]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[7]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[8]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[9]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[10]; count += 1; Vector[count] = allStepsContactForces.Single(m => m.Key == i).Value.Single(n => n.Key == elementsNumber + j).Value[11]; count += 1; } VectorOperations.PrintVectorToFile(Vector, @"C:\Users\Public\Documents\" + name); } for (int i = 0; i < allStepsSolutions.Count; i++) { allStepsFullSolutions.Add(i + 1, BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions.Single(m => m.Key == i + 1).Value, elementsAssembly.BoundedDOFsVector)); int j = i + 1; string name = "solution" + j.ToString() + ".dat"; VectorOperations.PrintVectorToFile(allStepsFullSolutions.Single(m => m.Key == i + 1).Value, @"C:\Users\Public\Documents\" + name); } List <double[]> structuralSolutions = new List <double[]>(); #endregion return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { ///Structural settings IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); ISolver newSolu = new StaticSolver(); newSolu.LinearScheme = new PCGSolver(); newSolu.NonLinearScheme = new LoadControlledNewtonRaphson(); newSolu.ActivateNonLinearSolver = true; newSolu.NonLinearScheme.numberOfLoadSteps = 1; //Thermal Settings IAssembly elementsAssembly2 = CreateThermalAssembly(); elementsAssembly2.CreateElementsAssembly(); elementsAssembly2.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix2 = elementsAssembly2.CreateTotalStiffnessMatrix(); ISolver thermalSolution = new StaticSolver(); thermalSolution.LinearScheme = new CholeskyFactorization(); thermalSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); thermalSolution.ActivateNonLinearSolver = true; thermalSolution.NonLinearScheme.numberOfLoadSteps = 10; //double[] externalFlux = new double[] { 0, 0, 0, 0, 250.0, 250.0 }; //newSolu2.AssemblyData = elementsAssembly; //newSolu2.Solve(externalForces); //newSolu2.PrintSolution(); //double[] tempSolution = newSolu.GetSolution(); double[] solVector2 = new double[6]; List <double[]> structuralSolutions = new List <double[]>(); for (int i = 1; i <= 5; i++) { newSolu.NonLinearScheme = new LoadControlledNewtonRaphson(solVector2); double[] externalForces2 = new double[] { 0, 0, 0, 0, -10000.0 * i, -10000.0 * i }; newSolu.AssemblyData = elementsAssembly; newSolu.Solve(externalForces2); solVector2 = newSolu.GetSolution(); structuralSolutions.Add(solVector2); } Dictionary <int, double[]> intForces = newSolu.GetInternalForces(); Dictionary <int, double[]> elementInternalForces = elementsAssembly.GetElementsInternalForces(structuralSolutions[0]); List <string> elementTypes = elementsAssembly.GetElementsType(); double[] temperatures = new double[6]; List <double[]> thermalSolutions = new List <double[]>(); for (int i = 1; i <= 5; i++) { thermalSolution.NonLinearScheme = new LoadControlledNewtonRaphson(temperatures); double[] externalHeatFlux = new double[] { 0, 0, 0, 0, 250.0, 250.0 }; thermalSolution.AssemblyData = elementsAssembly2; thermalSolution.Solve(externalHeatFlux); temperatures = thermalSolution.GetSolution(); thermalSolutions.Add(temperatures); } //double[] completeFinalSolutionVector = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solVector2, new int[] { 1, 2, 3, 4, 5, 7, 9, 11, 13, 15 }); Dictionary<int, INode> finalNodesList = new Dictionary<int, INode>(); //finalNodesList = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, completeFinalSolutionVector); return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
public static Results RunStaticExample() { #region Structural IAssembly elementsAssembly = CreateAssembly(); elementsAssembly.CreateElementsAssembly(); elementsAssembly.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix = elementsAssembly.CreateTotalStiffnessMatrix(); //Gnuplot graphs ShowToGUI.PlotInitialGeometry(elementsAssembly); Dictionary <int, INode> initialNodes = elementsAssembly.Nodes; double[] initialXCoord = Assembly.NodalCoordinatesToVectors(initialNodes).Item1; double[] initialYCoord = Assembly.NodalCoordinatesToVectors(initialNodes).Item2; double[] Xvec1Initial = new double[totalNodes / 2]; double[] Yvec1Initial = new double[totalNodes / 2]; double[] Xvec2Initial = new double[totalNodes / 2]; double[] Yvec2Initial = new double[totalNodes / 2]; double[] Ζvec1Initial = Enumerable.Repeat(1.0, totalNodes / 2).ToArray(); double[] Ζvec2Initial = Enumerable.Repeat(1.0, totalNodes / 2).ToArray(); Array.Copy(initialXCoord, 0, Xvec1Initial, 0, totalNodes / 2); Array.Copy(initialYCoord, 0, Yvec1Initial, 0, totalNodes / 2); Array.Copy(initialXCoord, totalNodes / 2, Xvec2Initial, 0, totalNodes / 2); Array.Copy(initialYCoord, totalNodes / 2, Yvec2Initial, 0, totalNodes / 2); //string pathForContour1 = @"C:\Users\Public\Documents\Total\1"; //string pathForContour2 = @"C:\Users\Public\Documents\Total\2"; //ExportToFile.CreateContourDataForMatlab(Xvec1Initial, Yvec1Initial, Ζvec1Initial, nodesInYCoor, nodesInXCoor, pathForContour1); //ExportToFile.CreateContourDataForMatlab(Xvec2Initial, Yvec2Initial, Ζvec2Initial, nodesInYCoor, nodesInXCoor, pathForContour2); //ISolver structuralSolution = new StaticSolver(); structuralSolution.LinearScheme = new PCGSolver(); //structuralSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); //structuralSolution.NonLinearScheme.Tolerance = 1e-5; structuralSolution.NonLinearScheme.Tolerance = 0.00001; //structuralSolution.NonLinearScheme.MaxIterations = 100; structuralSolution.ActivateNonLinearSolver = true; structuralSolution.NonLinearScheme.numberOfLoadSteps = 20; double[] externalForces3 = externalForcesStructuralVector; foreach (var dof in loadedStructuralDOFs) { if (dof == loadDof1 | dof == LoadDof2) { externalForces3[dof - 1] = externalStructuralLoad / 2; } else { externalForces3[dof - 1] = externalStructuralLoad; } } double[] reducedExternalForces3 = BoundaryConditionsImposition.ReducedVector(externalForces3, elementsAssembly.BoundedDOFsVector); structuralSolution.AssemblyData = elementsAssembly; structuralSolution.Solve(reducedExternalForces3); double[] solvector3 = structuralSolution.GetSolution(); elementsAssembly.UpdateDisplacements(solvector3); ShowToGUI.PlotFinalGeometry(elementsAssembly); double[] fullSolVector3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(solvector3, elementsAssembly.BoundedDOFsVector); Dictionary <int, INode> finalNodes = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVector3); double[] xFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item1; double[] yFinalNodalCoor = Assembly.NodalCoordinatesToVectors(finalNodes).Item2; Dictionary <int, double[]> allStepsSolutions = structuralSolution.GetAllStepsSolutions(); Dictionary <int, Dictionary <int, double[]> > allStepsContactForces = new Dictionary <int, Dictionary <int, double[]> >(); Dictionary <int, Dictionary <int, double> > allStepsContactDXs = new Dictionary <int, Dictionary <int, double> >(); Dictionary <int, Dictionary <int, double> > allStepsContactDXs1 = new Dictionary <int, Dictionary <int, double> >(); Dictionary <int, Dictionary <int, double> > allStepsContactDXs2 = new Dictionary <int, Dictionary <int, double> >(); Dictionary <int, Dictionary <int, INode> > allstepsfinalNodes = new Dictionary <int, Dictionary <int, INode> >(); //Dictionary<int, Dictionary<int, INode>> PreviusStatefinalNodes = new Dictionary<int, Dictionary<int, INode>>(); Dictionary <int, double[]> elementsInternalContactForcesVector; Dictionary <int, double> Deltax; Dictionary <int, double> Deltax1; Dictionary <int, double> Deltax2; //double[] SolutionSum = new double[2 * totalNodes]; double[] NodalX = new double[totalNodes]; double[] NodalY = new double[totalNodes]; int upperNode = new int(); int lowerLeftNode = new int(); int lowerRightNode = new int(); for (int i = 1; i <= allStepsSolutions.Count; i++) { elementsInternalContactForcesVector = new Dictionary <int, double[]>(); Deltax = new Dictionary <int, double>(); Deltax1 = new Dictionary <int, double>(); Deltax2 = new Dictionary <int, double>(); //allstepsfinalNodes = new Dictionary<int, Dictionary<int, INode>>(); double[] fullSolVectorSteps = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[i], elementsAssembly.BoundedDOFsVector); //SolutionSum = VectorOperations.VectorVectorAddition(SolutionSum, fullSolVectorSteps); allstepsfinalNodes[i] = Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullSolVectorSteps); elementsAssembly.UpdateDisplacements(allStepsSolutions[i]); NodalX = Assembly.NodalCoordinatesToVectors(allstepsfinalNodes[i]).Item1; NodalY = Assembly.NodalCoordinatesToVectors(allstepsfinalNodes[i]).Item2; for (int j = totalElements + 1; j <= totalElements + totalContactElements; j++) { elementsInternalContactForcesVector[j] = elementsAssembly.ElementsAssembly[j].CreateInternalGlobalForcesVector(); } upperNode = nodesInXCoor - totalContactElements + 1; lowerLeftNode = (nodesInXCoor + nodesInXCoor2) * nodesInYCoor - nodesInXCoor2 + 1; lowerRightNode = lowerLeftNode + 1; for (int j = totalElements + 1; j <= totalElements + totalContactElements; j += 2) { Deltax[j] = Math.Pow(Math.Pow(NodalX[lowerRightNode - 1] - NodalX[lowerLeftNode - 1], 2) + Math.Pow(NodalY[lowerRightNode - 1] - NodalY[lowerLeftNode - 1], 2), 0.5); Deltax2[j] = Math.Pow(Math.Pow(NodalX[lowerRightNode - 1] - NodalX[upperNode - 1], 2) + Math.Pow(NodalY[lowerRightNode - 1] - NodalY[upperNode - 1], 2), 0.5); Deltax1[j] = Math.Pow(Math.Pow(NodalX[upperNode - 1] - NodalX[lowerLeftNode - 1], 2) + Math.Pow(NodalY[upperNode - 1] - NodalY[lowerLeftNode - 1], 2), 0.5); upperNode = upperNode + 1; Deltax[j + 1] = Math.Pow(Math.Pow(NodalX[lowerRightNode - 1] - NodalX[lowerLeftNode - 1], 2) + Math.Pow(NodalY[lowerRightNode - 1] - NodalY[lowerLeftNode - 1], 2), 0.5); Deltax2[j + 1] = Math.Pow(Math.Pow(NodalX[lowerRightNode - 1] - NodalX[upperNode - 1], 2) + Math.Pow(NodalY[lowerRightNode - 1] - NodalY[upperNode - 1], 2), 0.5); Deltax1[j + 1] = Math.Pow(Math.Pow(NodalX[upperNode - 1] - NodalX[lowerLeftNode - 1], 2) + Math.Pow(NodalY[upperNode - 1] - NodalY[lowerLeftNode - 1], 2), 0.5); lowerLeftNode = lowerRightNode; lowerRightNode = lowerRightNode + 1; upperNode = upperNode + 1; } allStepsContactForces[i] = elementsInternalContactForcesVector; allStepsContactDXs[i] = Deltax; allStepsContactDXs1[i] = Deltax1; allStepsContactDXs2[i] = Deltax2; } List <double[]> structuralSolutions = new List <double[]>(); #endregion #region Thermal List <double[]> thermalSolutions = new List <double[]>(); //List<double[]> thermalSolutions2 = new List<double[]>(); List <Dictionary <int, double> > contactContactivityForEachStep = new List <Dictionary <int, double> >(); List <double[]> contactContactivityForEachStep2 = new List <double[]>(); for (int k = 1; k <= allStepsSolutions.Count; k++) { IAssembly elementsAssembly2 = CreateThermalAssembly(); for (int j = totalElements + 1; j <= totalElements + totalContactElements; j++) { double[] contactForce = allStepsContactForces[k][j]; double DX = allStepsContactDXs[k][j]; double DX1 = allStepsContactDXs1[k][j]; double DX2 = allStepsContactDXs2[k][j]; //double ContactForceVar = Math.Pow(Math.Pow(VectorOperations.VectorNorm2(new double[] { contactForce[4], contactForce[5] }),2),0.5); elementsAssembly2.ElementsProperties[j].ContactForceValue = VectorOperations.VectorNorm2(new double[] { contactForce[4], contactForce[5] }); elementsAssembly2.ElementsProperties[j].Dx = DX; elementsAssembly2.ElementsProperties[j].Dx1 = DX1; elementsAssembly2.ElementsProperties[j].Dx2 = DX2; } elementsAssembly2.CreateElementsAssembly(); elementsAssembly2.ActivateBoundaryConditions = true; double[,] globalStiffnessMatrix2 = elementsAssembly2.CreateTotalStiffnessMatrix(); ISolver thermalSolution = new StaticSolver(); thermalSolution.LinearScheme = new LUFactorization(); thermalSolution.NonLinearScheme = new LoadControlledNewtonRaphson(); thermalSolution.NonLinearScheme.Tolerance = 1e-7; thermalSolution.NonLinearScheme.MaxIterations = 100; thermalSolution.ActivateNonLinearSolver = true; thermalSolution.NonLinearScheme.numberOfLoadSteps = 10; thermalSolution.AssemblyData = elementsAssembly2; double[] externalHeatFlux = externalHeatLoafVector; //externalHeatFlux[0] = externalHeatLoad; //externalHeatFlux[15] = externalHeatLoad; //externalHeatFlux[30] = externalHeatLoad; //externalHeatFlux[45] = externalHeatLoad; //externalHeatFlux[60] = externalHeatLoad; foreach (var dof in loadedThermalDOFs) { if ((dof == ThermalDof1 | dof == ThermalDof2)) { externalHeatFlux[dof - 1] = -T0 * (cond / (6 * xIntervals * yIntervals)) * ((Math.Pow(xIntervals, 2) - 2 * Math.Pow(yIntervals, 2)) - (Math.Pow(xIntervals, 2) + Math.Pow(yIntervals, 2))); } else { externalHeatFlux[dof - 1] = -2 * T0 * (cond / (6 * xIntervals * yIntervals)) * ((Math.Pow(xIntervals, 2) - 2 * Math.Pow(yIntervals, 2)) - (Math.Pow(xIntervals, 2) + Math.Pow(yIntervals, 2))); } } //for (int i = 61; i <= 75; i++) //{ // externalHeatFlux[61] = externalHeatLoad; //} double[] reducedExternalHeatFlux = BoundaryConditionsImposition.ReducedVector(externalHeatFlux, thermalSolution.AssemblyData.BoundedDOFsVector); thermalSolution.Solve(reducedExternalHeatFlux); Dictionary <int, double[]> IntHeatFlux = thermalSolution.GetInternalForces(); //double [] HeatSolve= new double[totalNodes]; //double[] value; ////double[] Values = new double[totalNodes]; //for (int i = 1; i <= 10; i++) //{ // value = IntHeatFlux[i]; // thermalSolutions2.Add(value); // //Values[i - 1] = Convert.ToDouble(value); //} //HeatSolve = VectorOperations.VectorVectorAddition(Values , externalHeatFlux); double[] tempSol = thermalSolution.GetSolution(); elementsAssembly2.UpdateDisplacements(tempSol); //double[] contactContactivityVector = new double[totalContactElements]; //Dictionary<int, double[]> allStepsSolutions2 = thermalSolution.GetAllStepsSolutions(); thermalSolutions.Add(tempSol); //thermalSolutions2.Add(HeatSolve); Dictionary <int, double> contactContactivity = AssemblyHelpMethods.RetrieveContactContactivity(thermalSolution.AssemblyData); // contactContactivityForEachStep.Add(contactContactivity); // for (int i = 0; i <= totalContactElements - 1; i++) // { // contactContactivityVector[i] = contactContactivity[i + totalElements + 1]; // } // contactContactivityForEachStep2.Add(contactContactivityVector); } int[] thermalBoundCond = thermalBoundaryConditions; //int[] thermalBoundCond2 = thermalBoundaryConditions2; double[] fullStructuralSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[4], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[8], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[12], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[16], elementsAssembly.BoundedDOFsVector); double[] fullStructuralSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(allStepsSolutions[20], elementsAssembly.BoundedDOFsVector); double[] fullThermalSol1 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[3], thermalBoundCond); double[] fullThermalSol2 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[7], thermalBoundCond); double[] fullThermalSol3 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[11], thermalBoundCond); double[] fullThermalSol4 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[15], thermalBoundCond); double[] fullThermalSol5 = BoundaryConditionsImposition.CreateFullVectorFromReducedVector(thermalSolutions[19], thermalBoundCond); //double[] fullThermalSol6 = thermalSolutions2[19]; //double[] fullThermalSol7 = thermalSolutions2[39]; //double[] fullThermalSol8 = thermalSolutions2[59]; //double[] fullThermalSol9 = thermalSolutions2[79]; //double[] fullThermalSol10 = thermalSolutions2[99]; //double[] FullcontactContactivity1 = contactContactivityForEachStep2[1]; //double[] FullcontactContactivity2 = contactContactivityForEachStep2[3]; //double[] FullcontactContactivity3 = contactContactivityForEachStep2[5]; //double[] FullcontactContactivity4 = contactContactivityForEachStep2[7]; //double[] FullcontactContactivity5 = contactContactivityForEachStep2[9]; double[] FullStructuralSolution_1_Χ = new double[totalNodes]; double[] FullStructuralSolution_1_Υ = new double[totalNodes]; double[] FullStructuralSolution_2_Χ = new double[totalNodes]; double[] FullStructuralSolution_2_Υ = new double[totalNodes]; double[] FullStructuralSolution_3_Χ = new double[totalNodes]; double[] FullStructuralSolution_3_Υ = new double[totalNodes]; double[] FullStructuralSolution_4_Χ = new double[totalNodes]; double[] FullStructuralSolution_4_Υ = new double[totalNodes]; double[] FullStructuralSolution_5_Χ = new double[totalNodes]; double[] FullStructuralSolution_5_Υ = new double[totalNodes]; int count = 1; for (int i = 1; i <= 2 * totalNodes - 1; i += 2) { FullStructuralSolution_1_Χ[count - 1] = fullStructuralSol1[i - 1]; FullStructuralSolution_1_Υ[count - 1] = fullStructuralSol1[i]; count += 1; } count = 1; for (int i = 1; i <= 2 * totalNodes - 1; i += 2) { FullStructuralSolution_2_Χ[count - 1] = fullStructuralSol2[i - 1]; FullStructuralSolution_2_Υ[count - 1] = fullStructuralSol2[i]; count += 1; } count = 1; for (int i = 1; i <= 2 * totalNodes - 1; i += 2) { FullStructuralSolution_3_Χ[count - 1] = fullStructuralSol3[i - 1]; FullStructuralSolution_3_Υ[count - 1] = fullStructuralSol3[i]; count += 1; } count = 1; for (int i = 1; i <= 2 * totalNodes - 1; i += 2) { FullStructuralSolution_4_Χ[count - 1] = fullStructuralSol4[i - 1]; FullStructuralSolution_4_Υ[count - 1] = fullStructuralSol4[i]; count += 1; } count = 1; for (int i = 1; i <= 2 * totalNodes - 1; i += 2) { FullStructuralSolution_5_Χ[count - 1] = fullStructuralSol5[i - 1]; FullStructuralSolution_5_Υ[count - 1] = fullStructuralSol5[i]; count += 1; } ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol1), FullStructuralSolution_1_Χ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res1_ux.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol2), FullStructuralSolution_2_Χ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res2_ux.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol3), FullStructuralSolution_3_Χ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res3_ux.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol4), FullStructuralSolution_4_Χ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res4_ux.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol5), FullStructuralSolution_5_Χ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res5_ux.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol1), FullStructuralSolution_1_Υ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res1_uy.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol2), FullStructuralSolution_2_Υ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res2_uy.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol3), FullStructuralSolution_3_Υ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res3_uy.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol4), FullStructuralSolution_4_Υ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res4_uy.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol5), FullStructuralSolution_5_Υ, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.00Mpa_Res5_uy.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol1), fullThermalSol1, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.000Mpa_Res1_temp.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol2), fullThermalSol2, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.000Mpa_Res2_temp.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol3), fullThermalSol3, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.000Mpa_Res3_temp.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol4), fullThermalSol4, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.000Mpa_Res4_temp.dat"); ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol5), fullThermalSol5, @"C:\Users\Public\Documents\ThermalStructuralCNTsInAngle3_0.12L_20.000Mpa_Res5_temp.dat"); //ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol1), fullThermalSol6, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.90L_0.100Mpa_Res6.dat"); //ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol2), fullThermalSol7, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.90L_0.100Mpa_Res7.dat"); //ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol3), fullThermalSol8, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.90L_0.100Mpa_Res8.dat"); //ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol4), fullThermalSol9, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.90L_0.100Mpa_Res9.dat"); //ExportToFile.ExportGeometryDataWithTemperatures(Assembly.CalculateFinalNodalCoordinates(elementsAssembly.Nodes, fullStructuralSol5), fullThermalSol10, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.90L_0.100Mpa_Res10.dat"); //VectorOperations.PrintVectorToFile(fullThermalSol6, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_Res6.dat"); //VectorOperations.PrintVectorToFile(fullThermalSol7, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_Res7.dat"); //VectorOperations.PrintVectorToFile(fullThermalSol8, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_Res8.dat"); //VectorOperations.PrintVectorToFile(fullThermalSol9, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_Res9.dat"); //VectorOperations.PrintVectorToFile(fullThermalSol10, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_Res10.dat"); //VectorOperations.PrintVectorToFile(FullcontactContactivity1, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_CC1.dat"); //VectorOperations.PrintVectorToFile(FullcontactContactivity2, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_CC2.dat"); //VectorOperations.PrintVectorToFile(FullcontactContactivity3, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_CC3.dat"); //VectorOperations.PrintVectorToFile(FullcontactContactivity4, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_CC4.dat"); //VectorOperations.PrintVectorToFile(FullcontactContactivity5, @"C:\Users\Public\Documents\CouplThermStructCNTs_0.30L_0.100Mpa_CC5.dat"); double[] Xvec1Final = new double[totalNodes / 2]; double[] Yvec1Final = new double[totalNodes / 2]; double[] Xvec2Final = new double[totalNodes / 2]; double[] Yvec2Final = new double[totalNodes / 2]; double[] Ζvec1Final = new double[totalNodes / 2]; double[] Ζvec2Final = new double[totalNodes / 2]; Array.Copy(xFinalNodalCoor, 0, Xvec1Final, 0, totalNodes / 2); Array.Copy(yFinalNodalCoor, 0, Yvec1Final, 0, totalNodes / 2); Array.Copy(fullThermalSol4, 0, Ζvec1Final, 0, totalNodes / 2); Array.Copy(xFinalNodalCoor, totalNodes / 2, Xvec2Final, 0, totalNodes / 2); Array.Copy(yFinalNodalCoor, totalNodes / 2, Yvec2Final, 0, totalNodes / 2); Array.Copy(fullThermalSol4, totalNodes / 2, Ζvec2Final, 0, totalNodes / 2); List <HeatMapData> plots2 = new List <HeatMapData>(); plots2.Add(new HeatMapData() { Xcoordinates = Xvec1Final, Ycoordinates = Yvec1Final, Temperatures = Ζvec1Final }); plots2.Add(new HeatMapData() { Xcoordinates = Xvec2Final, Ycoordinates = Yvec2Final, Temperatures = Ζvec2Final }); ShowToGUI.PlotHeatMap(plots2); //string path = @"C:\Users\Public\Documents\Total\1final"; //string path2 = @"C:\Users\Public\Documents\Total\2final"; //ExportToFile.CreateContourDataForMatlab(Xvec1Final, Yvec1Final, Ζvec1Final, nodesInYCoor, nodesInXCoor, path); //ExportToFile.CreateContourDataForMatlab(Xvec2Final, Yvec2Final, Ζvec2Final, nodesInYCoor, nodesInXCoor, path2); //ExportToFile.ExportGeometryDataWithTemperatures(finalNodes, fullTempSol); GnuPlot.Close(); while (true) { if (File.Exists(AppContext.BaseDirectory + "gnuplot.png") && new FileInfo(AppContext.BaseDirectory + "gnuplot.png").Length > 0) { break; } Thread.Sleep(100); } GnuPlot.KillProcess(); #endregion return(new Results() { NonlinearSolution = structuralSolutions, SelectedDOF = 2, SolutionType = "Nonlinear" }); }
protected virtual double[,] CreateTotalStiffnessMatrix() { return(assembly.CreateTotalStiffnessMatrix()); }