public List <Vector <double> > CalcStrain(List <GH_Integer> c_e, Vector <double> u, List <Matrix <Double> > B_e, double E, double nu)
{
DataTree <double> treeStrain = new DataTree <double>();
Cmatrix C_new = new Cmatrix(E, nu);
Matrix <double> C = C_new.CreateMatrix();
StrainCalc sC = new StrainCalc();
List <Vector <double> > strain = new List <Vector <double> >();
//For calculating the strains and stress
strain = sC.calcStrain(B_e, u, c_e);
return(strain);
}
public List <Vector <double> > CalcStress(List <List <double> > globalStrain, double E, double nu)
{
List <Vector <double> > globalStress = new List <Vector <double> >();
Cmatrix C = new Cmatrix(E, nu);
Matrix <double> C_matrix = C.CreateMatrix();
for (int i = 0; i < globalStrain.Count; i++)
{
Vector <double> strainVec = Vector <double> .Build.Dense(globalStrain[i].ToArray());
globalStress.Add(C_matrix.Multiply(strainVec));
}
return(globalStress);
}
public List <List <Vector <double> > > CalcStrain(Vector <double> u, List <List <Matrix <double> > > B_all, GH_Structure <GH_Integer> treeConnectivity, double E, double nu)
{
List <Matrix <double> > B_e = new List <Matrix <double> >();
List <GH_Integer> c_e = new List <GH_Integer>();
DataTree <double> strain_node = new DataTree <double>();
Cmatrix C = new Cmatrix(E, nu);
Matrix <double> C_matrix = C.CreateMatrix();
List <List <Vector <double> > > strain = new List <List <Vector <double> > >();
for (int i = 0; i < B_all.Count; i++)
{
B_e = B_all[i];
c_e = (List <GH_Integer>)treeConnectivity.get_Branch(i);
List <Vector <double> > calcedStrain = CalcStrain(c_e, u, B_e, E, nu);
strain.Add(calcedStrain);
}
return(strain);
}
protected override void SolveInstance(IGH_DataAccess DA)
{
GH_Structure <GH_Integer> treeConnectivity = new GH_Structure <GH_Integer>();
GH_Structure <GH_Point> treePoints = new GH_Structure <GH_Point>();
List <string> bctxt = new List <string>();
List <string> loadtxt = new List <string>();
List <string> deftxt = new List <string>();
if (!DA.GetDataTree(0, out treeConnectivity))
{
return;
}
if (!DA.GetDataTree(1, out treePoints))
{
return;
}
if (!DA.GetDataList(2, bctxt))
{
return;
}
if (!DA.GetDataList(3, loadtxt))
{
return;
}
if (!DA.GetDataList(4, deftxt))
{
return;
}
// Temporary way of finding the size of stiffness matrix and B matrix
int sizeOfM = FindSizeOfM(treeConnectivity);
//List of global points with correct numbering
Point3d[] globalPoints = CreatePointList(treeConnectivity, treePoints, sizeOfM);
//Create K_tot
var tuple = CreateGlobalStiffnessMatrix(treeConnectivity, treePoints, sizeOfM);
double[,] K_tot = tuple.Item1;
//B_all
//List<List<Matrix<double>>> B_all = tuple.Item2;
Matrix <double>[,] B_all = tuple.Item2;
//Create boundary condition list AND predeformations
var tupleBC = CreateBCList(bctxt, globalPoints);
List <int> bcNodes = tupleBC.Item1;
var tupleDef = CreateBCList(deftxt, globalPoints);
List <int> predefNodes = tupleDef.Item1;
List <double> predef = tupleDef.Item2;
//Apply boundary condition and predeformations
K_tot = ApplyBC(K_tot, bcNodes);
K_tot = ApplyBC(K_tot, predefNodes);
//Needs to take the predefs into account
Vector <double> R_def = Vector <double> .Build.Dense(sizeOfM);
if (deftxt.Any())
{
R_def = ApplyPreDef(K_tot, predefNodes, predef, sizeOfM);
}
//Inverting K matrix
//Matrix<double> K_tot_inverse = K_tot.Inverse();
//double[] R_array = SetLoads(sizeOfM, loadtxt);
double[] R_array = AssignLoadsAndBC(loadtxt, bcNodes, globalPoints);
var V = Vector <double> .Build;
var R = (V.DenseOfArray(R_array)).Subtract(R_def);
double[] R_array_def = new double[sizeOfM];
for (int j = 0; j < sizeOfM; j++)
{
R_array_def[j] = R[j];
}
//Caluculation of the displacement vector u
//Vector<double> u = K_tot_inverse.Multiply(R);
//Trying with cholesky
Deformations def = new Deformations(K_tot, R_array_def);
List <double> u = def.Cholesky_Banachiewicz();
DataTree <double> defTree = new DataTree <double>();
int n = 0;
for (int i = 0; i < u.Count; i += 3)
{
List <double> u_node = new List <double>(3);
u_node.Add(u[i]);
u_node.Add(u[i + 1]);
u_node.Add(u[i + 2]);
defTree.AddRange(u_node, new GH_Path(new int[] { 0, n }));
n++;
}
//Calculatin strains for each node and stresses based on strain.
List <Matrix <double> > B_e = new List <Matrix <double> >();
List <GH_Integer> c_e = new List <GH_Integer>();
DataTree <double> strain_node = new DataTree <double>();
Cmatrix C = new Cmatrix(E, nu);
Matrix <double> C_matrix = C.CreateMatrix();
//List<List<Vector<double>>> strain = new List<List<Vector<double>>>();
Vector <double>[,] strain = CalcStrain(treeConnectivity, u, B_all);
DataTree <double> strainTree = new DataTree <double>();
DataTree <double> stressTree = new DataTree <double>();
double[,] globalStrain = FindGlobalStrain(strain, treeConnectivity, sizeOfM);
Vector <double>[] globalStress = CalcStress(globalStrain, C_matrix);
for (int i = 0; i < globalStrain.GetLength(0); i++)
{
//strainTree.AddRange(globalStrain[i], new GH_Path(new int[] { 0, i }));
stressTree.AddRange(globalStress[i], new GH_Path(new int[] { 0, i }));
for (int j = 0; j < globalStrain.GetLength(1); j++)
{
strainTree.Add(globalStrain[i, j], new GH_Path(new int[] { 0, i }));
}
}
DA.SetDataTree(0, defTree);
DA.SetDataTree(1, strainTree);
DA.SetDataTree(2, stressTree);
DA.SetDataList(3, globalPoints);
/*
* GH_Boolean => Boolean
* GH_Integer => int
* GH_Number => double
* GH_Vector => Vector3d
* GH_Matrix => Matrix
* GH_Surface => Brep
*/
}
