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example.cpp
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Sun, Apr 28, 20:58

example.cpp
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#include <GMatElastic/Cartesian3d.h>
#include <GooseFEM/GooseFEM.h>
#include <GooseFEM/MatrixPartitioned.h>
#include <highfive/H5Easy.hpp>
int main()
{
// mesh
// ----
// define mesh
GooseFEM::Mesh::Quad4::Regular mesh(5, 5);
// mesh dimensions
size_t nelem = mesh.nelem();
size_t nne = mesh.nne();
size_t ndim = mesh.ndim();
// mesh definitions
xt::xtensor<double, 2> coor = mesh.coor();
xt::xtensor<size_t, 2> conn = mesh.conn();
xt::xtensor<size_t, 2> dofs = mesh.dofs();
// node sets
xt::xtensor<size_t, 1> nodesLft = mesh.nodesLeftEdge();
xt::xtensor<size_t, 1> nodesRgt = mesh.nodesRightEdge();
xt::xtensor<size_t, 1> nodesTop = mesh.nodesTopEdge();
xt::xtensor<size_t, 1> nodesBot = mesh.nodesBottomEdge();
// fixed displacements DOFs
// ------------------------
xt::xtensor<size_t, 1> iip = xt::concatenate(xt::xtuple(
xt::view(dofs, xt::keep(nodesRgt), 0),
xt::view(dofs, xt::keep(nodesTop), 1),
xt::view(dofs, xt::keep(nodesLft), 0),
xt::view(dofs, xt::keep(nodesBot), 1)));
// simulation variables
// --------------------
// vector definition
GooseFEM::VectorPartitioned vector(conn, dofs, iip);
// allocate system matrix
GooseFEM::MatrixPartitioned K(conn, dofs, iip);
GooseFEM::MatrixPartitionedSolver<> Solver;
// nodal quantities
xt::xtensor<double, 2> disp = xt::zeros<double>(coor.shape());
xt::xtensor<double, 2> fint = xt::zeros<double>(coor.shape());
xt::xtensor<double, 2> fext = xt::zeros<double>(coor.shape());
xt::xtensor<double, 2> fres = xt::zeros<double>(coor.shape());
// element vectors
xt::xtensor<double, 3> ue = xt::empty<double>({nelem, nne, ndim});
xt::xtensor<double, 3> fe = xt::empty<double>({nelem, nne, ndim});
xt::xtensor<double, 3> Ke = xt::empty<double>({nelem, nne * ndim, nne * ndim});
// element/material definition
// ---------------------------
// element definition
GooseFEM::Element::Quad4::QuadraturePlanar elem(vector.AsElement(coor));
size_t nip = elem.nip();
// material definition
GMatElastic::Cartesian3d::Matrix mat(nelem, nip, 1.0, 1.0);
// integration point tensors
xt::xtensor<double, 4> Eps = xt::empty<double>({nelem, nip, 3ul, 3ul});
xt::xtensor<double, 4> Sig = xt::empty<double>({nelem, nip, 3ul, 3ul});
xt::xtensor<double, 6> C = xt::empty<double>({nelem, nip, 3ul, 3ul, 3ul, 3ul});
// solve
// -----
// strain
vector.asElement(disp, ue);
elem.symGradN_vector(ue, Eps);
// stress & tangent
mat.tangent(Eps, Sig, C);
// internal force
elem.int_gradN_dot_tensor2_dV(Sig, fe);
vector.assembleNode(fe, fint);
// stiffness matrix
elem.int_gradN_dot_tensor4_dot_gradNT_dV(C, Ke);
K.assemble(Ke);
// set fixed displacements
xt::view(disp, xt::keep(nodesRgt), 0) = +0.1;
xt::view(disp, xt::keep(nodesTop), 1) = -0.1;
xt::view(disp, xt::keep(nodesLft), 0) = 0.0;
xt::view(disp, xt::keep(nodesBot), 1) = 0.0;
// residual
xt::noalias(fres) = fext - fint;
// solve
Solver.solve(K, fres, disp);
// post-process
// ------------
// compute strain and stress
vector.asElement(disp, ue);
elem.symGradN_vector(ue, Eps);
mat.stress(Eps, Sig);
// internal force
elem.int_gradN_dot_tensor2_dV(Sig, fe);
vector.assembleNode(fe, fint);
// apply reaction force
vector.copy_p(fint, fext);
// residual
xt::noalias(fres) = fext - fint;
// print residual
std::cout << xt::sum(xt::abs(fres))[0] / xt::sum(xt::abs(fext))[0] << std::endl;
// average stress per node
xt::xtensor<double, 4> dV = elem.AsTensor<2>(elem.dV());
xt::xtensor<double, 3> SigAv = xt::average(Sig, dV, {1});
// write output
H5Easy::File file("output.h5", H5Easy::File::Overwrite);
H5Easy::dump(file, "/coor", coor);
H5Easy::dump(file, "/conn", conn);
H5Easy::dump(file, "/disp", disp);
H5Easy::dump(file, "/Sig", SigAv);
return 0;
}

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