Exemplo n.º 1
0
Real
StressDivergence::computeQpJacobian()
{
  Real sum_C3x3 = _Jacobian_mult[_qp].sum_3x3();
  RealGradient sum_C3x1 = _Jacobian_mult[_qp].sum_3x1();

  Real jacobian = 0.0;
  // B^T_i * C * B_j
  jacobian += _Jacobian_mult[_qp].stiffness(
      _component, _component, _grad_test[_i][_qp], _grad_phi[_j][_qp]); // B^T_i * C *B_j

  if (_volumetric_locking_correction)
  {
    // jacobian = Bbar^T_i * C * Bbar_j where Bbar = B + Bvol
    // jacobian = B^T_i * C * B_j + Bvol^T_i * C * Bvol_j +  Bvol^T_i * C * B_j + B^T_i * C * Bvol_j

    // Bvol^T_i * C * Bvol_j
    jacobian += sum_C3x3 * (_avg_grad_test[_i][_component] - _grad_test[_i][_qp](_component)) *
                (_avg_grad_phi[_j][_component] - _grad_phi[_j][_qp](_component)) / 9.0;

    // B^T_i * C * Bvol_j
    jacobian += sum_C3x1(_component) * _grad_test[_i][_qp](_component) *
                (_avg_grad_phi[_j][_component] - _grad_phi[_j][_qp](_component)) / 3.0;

    // Bvol^T_i * C * B_j
    SymmTensor phi;
    if (_component == 0)
    {
      phi.xx() = _grad_phi[_j][_qp](0);
      phi.xy() = _grad_phi[_j][_qp](1);
      phi.xz() = _grad_phi[_j][_qp](2);
    }
    else if (_component == 1)
    {
      phi.yy() = _grad_phi[_j][_qp](1);
      phi.xy() = _grad_phi[_j][_qp](0);
      phi.yz() = _grad_phi[_j][_qp](2);
    }
    else if (_component == 2)
    {
      phi.zz() = _grad_phi[_j][_qp](2);
      phi.xz() = _grad_phi[_j][_qp](0);
      phi.yz() = _grad_phi[_j][_qp](1);
    }

    SymmTensor tmp(_Jacobian_mult[_qp] * phi);

    jacobian += (tmp.xx() + tmp.yy() + tmp.zz()) *
                (_avg_grad_test[_i][_component] - _grad_test[_i][_qp](_component)) / 3.0;
  }

  if (_dt > 0)
    return jacobian * (1 + _alpha + _zeta / _dt);
  else
    return jacobian;
}
Exemplo n.º 2
0
ColumnMajorMatrix
CrackFrontDefinition::rotateToCrackFrontCoords(const SymmTensor tensor, const unsigned int node_index) const
{
  ColumnMajorMatrix tensor_CMM;
  tensor_CMM(0,0) = tensor.xx();
  tensor_CMM(0,1) = tensor.xy();
  tensor_CMM(0,2) = tensor.xz();
  tensor_CMM(1,0) = tensor.xy();
  tensor_CMM(1,1) = tensor.yy();
  tensor_CMM(1,2) = tensor.yz();
  tensor_CMM(2,0) = tensor.xz();
  tensor_CMM(2,1) = tensor.yz();
  tensor_CMM(2,2) = tensor.zz();

  ColumnMajorMatrix tmp = _rot_matrix[node_index] * tensor_CMM;
  ColumnMajorMatrix rotT = _rot_matrix[node_index].transpose();
  ColumnMajorMatrix rotated_tensor = tmp * rotT;

  return rotated_tensor;
}
Exemplo n.º 3
0
Real
StressDivergence::computeQpOffDiagJacobian(unsigned int jvar)
{
  unsigned int coupled_component = 0;

  bool active = false;

  if (_xdisp_coupled && jvar == _xdisp_var)
  {
    coupled_component = 0;
    active = true;
  }
  else if (_ydisp_coupled && jvar == _ydisp_var)
  {
    coupled_component = 1;
    active = true;
  }
  else if (_zdisp_coupled && jvar == _zdisp_var)
  {
    coupled_component = 2;
    active = true;
  }

  if (active)
  {
    Real sum_C3x3 = _Jacobian_mult[_qp].sum_3x3();
    RealGradient sum_C3x1 = _Jacobian_mult[_qp].sum_3x1();
    Real jacobian = 0.0;
    jacobian += _Jacobian_mult[_qp].stiffness(
        _component, coupled_component, _grad_test[_i][_qp], _grad_phi[_j][_qp]); // B^T_i * C *B_j

    if (_volumetric_locking_correction)
    {
      // jacobian = Bbar^T_i * C * Bbar_j where Bbar = B + Bvol
      // jacobian = B^T_i * C * B_j + Bvol^T_i * C * Bvol_j +  Bvol^T_i * C * B_j + B^T_i * C *
      // Bvol_j

      // Bvol^T_i * C * Bvol_j
      jacobian += sum_C3x3 * (_avg_grad_test[_i][_component] - _grad_test[_i][_qp](_component)) *
                  (_avg_grad_phi[_j][coupled_component] - _grad_phi[_j][_qp](coupled_component)) /
                  9.0;

      // B^T_i * C * Bvol_j
      jacobian += sum_C3x1(_component) * _grad_test[_i][_qp](_component) *
                  (_avg_grad_phi[_j][coupled_component] - _grad_phi[_j][_qp](coupled_component)) /
                  3.0;

      // Bvol^T_i * C * B_i
      SymmTensor phi;
      if (coupled_component == 0)
      {
        phi.xx() = _grad_phi[_j][_qp](0);
        phi.xy() = _grad_phi[_j][_qp](1);
        phi.xz() = _grad_phi[_j][_qp](2);
      }
      else if (coupled_component == 1)
      {
        phi.yy() = _grad_phi[_j][_qp](1);
        phi.xy() = _grad_phi[_j][_qp](0);
        phi.yz() = _grad_phi[_j][_qp](2);
      }
      else if (coupled_component == 2)
      {
        phi.zz() = _grad_phi[_j][_qp](2);
        phi.xz() = _grad_phi[_j][_qp](0);
        phi.yz() = _grad_phi[_j][_qp](1);
      }

      SymmTensor tmp(_Jacobian_mult[_qp] * phi);

      jacobian += (tmp.xx() + tmp.yy() + tmp.zz()) *
                  (_avg_grad_test[_i][_component] - _grad_test[_i][_qp](_component)) / 3.0;
    }

    if (_dt > 0)
      return jacobian * (1 + _alpha + _zeta / _dt);
    else
      return jacobian;
  }

  if (_temp_coupled && jvar == _temp_var)
    return _d_stress_dT[_qp].rowDot(_component, _grad_test[_i][_qp]) * _phi[_j][_qp];

  return 0;
}