/* == Incompressible deformation: non-zero displacement boundary conditions, functional tractions ==
     *
     * We now consider a more complicated example. We prescribe particular new locations for the nodes
     * on the Dirichlet boundary, and also show how to prescribe a traction that is given in functional form
     * rather than prescribed for each boundary element.
     */
    void TestIncompressibleProblemMoreComplicatedExample() throw(Exception)
    {
        /* Create a mesh */
        QuadraticMesh<2> mesh;
        mesh.ConstructRegularSlabMesh(0.1 /*stepsize*/, 1.0 /*width*/, 1.0 /*height*/);

        /* Use a different material law this time, an exponential material law.
         * The material law needs to inherit from `AbstractIncompressibleMaterialLaw`,
         * and there are a few implemented, see `continuum_mechanics/src/problem/material_laws` */
        ExponentialMaterialLaw<2> law(1.0, 0.5); // First parameter is 'a', second 'b', in W=a*exp(b(I1-3))
        /* Now specify the fixed nodes, and their new locations. Create `std::vector`s for each. */
        std::vector<unsigned> fixed_nodes;
        std::vector<c_vector<double,2> > locations;
        /* Loop over the mesh nodes */
        for (unsigned i=0; i<mesh.GetNumNodes(); i++)
        {
            /* If the node is on the Y=0 surface (the LHS) */
            if ( fabs(mesh.GetNode(i)->rGetLocation()[1])<1e-6)
            {
                /* Add it to the list of fixed nodes */
                fixed_nodes.push_back(i);
                /* and define a new position x=(X,0.1*X^2^) */
                c_vector<double,2> new_location;
                double X = mesh.GetNode(i)->rGetLocation()[0];
                new_location(0) = X;
                new_location(1) = 0.1*X*X;
                locations.push_back(new_location);
            }
        }

        /* Now collect all the boundary elements on the top surface, as before, except
         * here we don't create the tractions for each element
         */
        std::vector<BoundaryElement<1,2>*> boundary_elems;
        for (TetrahedralMesh<2,2>::BoundaryElementIterator iter = mesh.GetBoundaryElementIteratorBegin();
             iter != mesh.GetBoundaryElementIteratorEnd();
             ++iter)
        {
            /* If Y=1, have found a boundary element */
            if (fabs((*iter)->CalculateCentroid()[1] - 1.0)<1e-6)
            {
                BoundaryElement<1,2>* p_element = *iter;
                boundary_elems.push_back(p_element);
            }
        }

        /* Create a problem definition object, and this time calling `SetFixedNodes`
         * which takes in the new locations of the fixed nodes.
         */
        SolidMechanicsProblemDefinition<2> problem_defn(mesh);
        problem_defn.SetMaterialLaw(INCOMPRESSIBLE,&law);
        problem_defn.SetFixedNodes(fixed_nodes, locations);
        /* Now call `SetTractionBoundaryConditions`, which takes in a vector of
         * boundary elements as in the previous test. However this time the second argument
         * is a ''function pointer'' (just the name of the function) to a
         * function returning traction in terms of position (and time [see below]).
         * This function is defined above, before the tests. It has to take in a `c_vector` (position)
         *  and a double (time), and returns a `c_vector` (traction), and will only be called
         * using points in the boundary elements being passed in. The function `MyTraction`
         * (defined above, before the tests) above defines a horizontal traction (ie a shear stress, since it is
         * applied to the top surface) which increases in magnitude across the object.
          */
        problem_defn.SetTractionBoundaryConditions(boundary_elems, MyTraction);
        /* Note: You can also call `problem_defn.SetBodyForce(MyBodyForce)`, passing in a function
         * instead of a vector, although isn't really physically useful, it is only really useful
         * for constructing problems with exact solutions.
         *
         * Create the solver as before */
        IncompressibleNonlinearElasticitySolver<2> solver(mesh,
                                                          problem_defn,
                                                          "IncompressibleElasticityMoreComplicatedExample");


        /* Call `Solve()` */
        solver.Solve();

        /* Another quick check */
        TS_ASSERT_EQUALS(solver.GetNumNewtonIterations(), 6u);
        /* Visualise as before.
         *
         * '''Advanced:''' Note that the function `MyTraction` takes in time, which it didn't use. In the above it would have been called
         * with t=0. The current time can be set using `SetCurrentTime()`. The idea is that the user may want to solve a
         * sequence of static problems with time-dependent tractions (say), for which they should allow `MyTraction` to
         * depend on time, and put the solve inside a time-loop, for example:
         */
        //for (double t=0; t<T; t+=dt)
        //{
        //    solver.SetCurrentTime(t);
        //    solver.Solve();
        //}
        /* In this the current time would be passed through to `MyTraction`
         *
         * Create Cmgui output
         */
        solver.CreateCmguiOutput();

        /* This is just to check that nothing has been accidentally changed in this test */
        TS_ASSERT_DELTA(solver.rGetDeformedPosition()[98](0), 1.4543, 1e-3);
        TS_ASSERT_DELTA(solver.rGetDeformedPosition()[98](1), 0.5638, 1e-3);
    }
    /* == Compressible deformation, and other bits and pieces ==
     *
     * In this test, we will show the (very minor) changes required to solve a compressible nonlinear
     * elasticity problem, we will describe and show how to specify 'pressure on deformed body'
     * boundary conditions, we illustrate how a quadratic mesh can be generated using a linear mesh
     * input files, and we also illustrate how `Solve()` can be called repeatedly, with loading
     * changing between the solves.
     *
     * Note: for other examples of compressible solves, including problems with an exact solution, see the
     * file `continuum_mechanics/test/TestCompressibleNonlinearElasticitySolver.hpp`
     */
    void TestSolvingCompressibleProblem() throw (Exception)
    {
        /* All mechanics problems must take in quadratic meshes, but the mesh files for
         * (standard) linear meshes in Triangles/Tetgen can be automatically converted
         * to quadratic meshes, by simply doing the following. (The mesh loaded here is a disk
         * centred at the origin with radius 1).
         */
        QuadraticMesh<2> mesh;
        TrianglesMeshReader<2,2> reader("mesh/test/data/disk_522_elements");
        mesh.ConstructFromLinearMeshReader(reader);

        /* Compressible problems require a compressible material law, ie one that
         * inherits from `AbstractCompressibleMaterialLaw`. The `CompressibleMooneyRivlinMaterialLaw`
         * is one such example; instantiate one of these
         */
        CompressibleMooneyRivlinMaterialLaw<2> law(1.0, 0.5);

        /* For this problem, we fix the nodes on the surface for which Y < -0.9 */
        std::vector<unsigned> fixed_nodes;
        for ( TetrahedralMesh<2,2>::BoundaryNodeIterator iter = mesh.GetBoundaryNodeIteratorBegin();
              iter != mesh.GetBoundaryNodeIteratorEnd();
              ++iter)
        {
            double Y = (*iter)->rGetLocation()[1];
            if(Y < -0.9)
            {
                fixed_nodes.push_back((*iter)->GetIndex());
            }
        }

        /* We will (later) apply Neumann boundary conditions to surface elements which lie below Y=0,
         * and these are collected here. (Minor, subtle, comment: we don't bother here checking Y>-0.9,
         * so the surface elements collected here include the ones on the Dirichlet boundary. This doesn't
         * matter as the Dirichlet boundary conditions to the nonlinear system essentially overwrite
         * an Neumann-related effects).
         */
        std::vector<BoundaryElement<1,2>*> boundary_elems;
        for (TetrahedralMesh<2,2>::BoundaryElementIterator iter
              = mesh.GetBoundaryElementIteratorBegin();
            iter != mesh.GetBoundaryElementIteratorEnd();
            ++iter)
        {
           BoundaryElement<1,2>* p_element = *iter;
           if(p_element->CalculateCentroid()[1]<0.0)
           {
               boundary_elems.push_back(p_element);
           }
        }
        assert(boundary_elems.size()>0);

        /* Create the problem definition class, and set the law again, this time
         * stating that the law is compressible
         */
        SolidMechanicsProblemDefinition<2> problem_defn(mesh);
        problem_defn.SetMaterialLaw(COMPRESSIBLE,&law);

        /* Set the fixed nodes and gravity */
        problem_defn.SetZeroDisplacementNodes(fixed_nodes);

        /* The elasticity solvers have two nonlinear solvers implemented, one hand-coded and one which uses PETSc's SNES
         * solver. The latter is not the default but can be more robust (and will probably be the default in later
         * versions). This is how it can be used. (This option can also be called if the compiled binary is run from
         * the command line (see ChasteGuides/RunningBinariesFromCommandLine) using the option "-mech_use_snes").
         */
        problem_defn.SetSolveUsingSnes();
        /* This line tells the solver to output info about the nonlinear solve as it progresses, and can be used with
         * or without the SNES option above. The corresponding command line option is "-mech_verbose"
         */
        problem_defn.SetVerboseDuringSolve();

        c_vector<double,2> gravity;
        gravity(0) = 0;
        gravity(1) = 0.1;
        problem_defn.SetBodyForce(gravity);

        /* Declare the compressible solver, which has the same interface as the incompressible
         * one, and call `Solve()`
         */
        CompressibleNonlinearElasticitySolver<2> solver(mesh,
                                                        problem_defn,
                                                        "CompressibleSolidMechanicsExample");
        solver.Solve();

        /* Now we call add additional boundary conditions, and call `Solve() again. Firstly: these
         * Neumann conditions here are not specified traction boundary conditions (such BCs are specified
         * on the undeformed body), but instead, the (more natural) specification of a pressure
         * exactly in the ''normal direction on the deformed body''. We have to provide a set of boundary
         * elements of the mesh, and a pressure to act on those elements. The solver will automatically
         * compute the deformed normal directions on which the pressure acts. Note: with this type of
         * BC, the ordering of the nodes on the boundary elements needs to be consistent, otherwise some
         * normals will be computed to be inward and others outward. The solver will check this on the
         * original mesh and throw an exception if this is not the case. (The required ordering is such that:
         * in 2D, surface element nodes are ordered anticlockwise (looking at the whole mesh); in 3D, looking
         * at any surface element from outside the mesh, the three nodes are ordered anticlockwise. (Triangle/tetgen
         * automatically create boundary elements like this)).
         */
        double external_pressure = -0.4; // negative sign => inward pressure
        problem_defn.SetApplyNormalPressureOnDeformedSurface(boundary_elems, external_pressure);
        /* Call `Solve()` again, so now solving with fixed nodes, gravity, and pressure. The solution from
         * the previous solve will be used as the initial guess. Although at the moment the solution from the
         * previous call to `Solve()` will be over-written, calling `Solve()` repeatedly may be useful for
         * some problems: sometimes, Newton's method will fail to converge for given force/pressures etc, and it can
         * be (very) helpful to ''increment'' the loading. For example, set the gravity to be (0,-9.81/3), solve,
         * then set it to be (0,-2*9.81/3), solve again, and finally set it to be (0,-9.81) and solve for a
         * final time
         */
        solver.Solve();
        solver.CreateCmguiOutput();
    }
    /* == Incompressible deformation: 2D shape hanging under gravity with a balancing traction ==
     *
     * We now repeat the above test but include a traction on the bottom surface (Y=0). We apply this
     * in the inward direction so that is counters (somewhat) the effect of gravity. We also show how stresses
     * and strains can be written to file.
     */
    void TestIncompressibleProblemWithTractions() throw(Exception)
    {
        /* All of this is exactly as above */
        QuadraticMesh<2> mesh;
        mesh.ConstructRegularSlabMesh(0.1 /*stepsize*/, 0.8 /*width*/, 1.0 /*height*/);

        MooneyRivlinMaterialLaw<2> law(1.0);

        c_vector<double,2> body_force;
        body_force(0) =  0.0;
        body_force(1) = -2.0;

        std::vector<unsigned> fixed_nodes = NonlinearElasticityTools<2>::GetNodesByComponentValue(mesh, 1, 1.0);

        /* Now the traction boundary conditions. We need to collect all the boundary elements on the surface which we want to
         * apply non-zero tractions, put them in a `std::vector`, and create a corresponding `std::vector` of the tractions
         * for each of the boundary elements. Note that the each traction is a 2D vector with dimensions of pressure.
         *
         * First, declare the data structures:
         */
        std::vector<BoundaryElement<1,2>*> boundary_elems;
        std::vector<c_vector<double,2> > tractions;
        /* Create a constant traction */
        c_vector<double,2> traction;
        traction(0) = 0;
        traction(1) = 1.0; // this choice of sign corresponds to an inward force (if applied to the bottom surface)
        /* Loop over boundary elements */
        for (TetrahedralMesh<2,2>::BoundaryElementIterator iter = mesh.GetBoundaryElementIteratorBegin();
             iter != mesh.GetBoundaryElementIteratorEnd();
             ++iter)
        {
            /* If the centre of the element has Y value of 0.0, it is on the surface we need */
            if (fabs((*iter)->CalculateCentroid()[1] - 0.0) < 1e-6)
            {
                /* Put the boundary element and the constant traction into the stores. */
                BoundaryElement<1,2>* p_element = *iter;
                boundary_elems.push_back(p_element);
                tractions.push_back(traction);
            }
        }
        /* A quick check */
        assert(boundary_elems.size() == 8u);

        /* Now create the problem definition object, setting the material law, fixed nodes and body force as
         * before (this time not calling `SetDensity()`, so using the default density of 1.0,
         * and also calling a method for setting tractions, which takes in the boundary elements
         * and tractions for each of those elements.
         */
        SolidMechanicsProblemDefinition<2> problem_defn(mesh);
        problem_defn.SetMaterialLaw(INCOMPRESSIBLE,&law);
        problem_defn.SetZeroDisplacementNodes(fixed_nodes);
        problem_defn.SetBodyForce(body_force);
        problem_defn.SetTractionBoundaryConditions(boundary_elems, tractions);

        /* Create solver as before */
        IncompressibleNonlinearElasticitySolver<2> solver(mesh,
                                                          problem_defn,
                                                          "IncompressibleElasticityWithTractionsTutorial");

        /* In this test we also output the stress and strain. For the former, we have to tell the solver to store
         * the stresses that are computed during the solve.
         */
        solver.SetComputeAverageStressPerElementDuringSolve();


        /* Call `Solve()` */
        solver.Solve();

        /* If VTK output is written (discussed above) strains can be visualised. Alternatively, we can create text files
         * for strains and stresses by doing the following.
         *
         * Write the final deformation gradients to file. The i-th line of this file provides the deformation gradient F,
         * written as 'F(0,0) F(0,1) F(1,0) F(1,1)', evaluated at the centroid of the i-th element. The first variable
         * can also be DEFORMATION_TENSOR_C or LAGRANGE_STRAIN_E to write C or E. The second parameter is the file name.
         */
        solver.WriteCurrentStrains(DEFORMATION_GRADIENT_F,"deformation_grad");

        /* Since we called `SetComputeAverageStressPerElementDuringSolve`, we can write the stresses to file too. However,
         * note that for each element this is not the stress evaluated at the centroid, but the mean average of the stresses
         * evaluated at the quadrature points - for technical cardiac electromechanics reasons, it is difficult to
         * define the stress at non-quadrature points.
         */
        solver.WriteCurrentAverageElementStresses("2nd_PK_stress");


        /* Another quick check */
        TS_ASSERT_EQUALS(solver.GetNumNewtonIterations(), 4u);

        /* Visualise as before by going to the output directory and doing
         * `x=load('solution.nodes'); plot(x(:,1),x(:,2),'m*')` in Matlab/octave, or by using Cmgui.
         * The effect of the traction should be clear (especially when compared to
         * the results of the first test).
         *
         * Create Cmgui output
         */
        solver.CreateCmguiOutput();

        /* This is just to check that nothing has been accidentally changed in this test */
        TS_ASSERT_DELTA(solver.rGetDeformedPosition()[8](0), 0.8561, 1e-3);
        TS_ASSERT_DELTA(solver.rGetDeformedPosition()[8](1), 0.0310, 1e-3);
    }
    void TestAssembler2d() throw (Exception)
    {
        QuadraticMesh<2> mesh;
        TrianglesMeshReader<2,2> mesh_reader("mesh/test/data/canonical_triangle_quadratic", 2, 2, false);
        mesh.ConstructFromMeshReader(mesh_reader);

        ContinuumMechanicsProblemDefinition<2> problem_defn(mesh);

        double t1 = 2.6854233;
        double t2 = 3.2574578;

        // for the boundary element on the y=0 surface, create a traction
        std::vector<BoundaryElement<1,2>*> boundary_elems;
        std::vector<c_vector<double,2> > tractions;
        c_vector<double,2> traction;
        traction(0) = t1;
        traction(1) = t2;
        for (TetrahedralMesh<2,2>::BoundaryElementIterator iter
              = mesh.GetBoundaryElementIteratorBegin();
             iter != mesh.GetBoundaryElementIteratorEnd();
             ++iter)
        {
            if (fabs((*iter)->CalculateCentroid()[1])<1e-4)
            {
                BoundaryElement<1,2>* p_element = *iter;
                boundary_elems.push_back(p_element);
                tractions.push_back(traction);
            }
        }
        assert(boundary_elems.size()==1);
        problem_defn.SetTractionBoundaryConditions(boundary_elems, tractions);


        ContinuumMechanicsNeumannBcsAssembler<2> assembler(&mesh, &problem_defn);

        TS_ASSERT_THROWS_THIS(assembler.AssembleVector(), "Vector to be assembled has not been set");
        Vec bad_sized_vec = PetscTools::CreateVec(2);
        assembler.SetVectorToAssemble(bad_sized_vec, true);
        TS_ASSERT_THROWS_THIS(assembler.AssembleVector(), "Vector provided to be assembled has size 2, not expected size of 18 ((dim+1)*num_nodes)");


        Vec vec = PetscTools::CreateVec(3*mesh.GetNumNodes());

        assembler.SetVectorToAssemble(vec, true);
        assembler.AssembleVector();

        ReplicatableVector vec_repl(vec);

        // Note: on a 1d boundary element,  intgl phi_i dx = 1/6 for the bases on the vertices
        // and intgl phi_i dx = 4/6 for the basis at the interior node. (Here the integrals
        // are over the canonical 1d element, [0,1], which is also the physical element for this
        // mesh.

        // node 0 is on the surface, and is a vertex
        TS_ASSERT_DELTA(vec_repl[0], t1/6.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[1], t2/6.0, 1e-8);

        // node 1 is on the surface, and is a vertex
        TS_ASSERT_DELTA(vec_repl[3], t1/6.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[4], t2/6.0, 1e-8);

        // nodes 2, 3, 4 are not on the surface
        for(unsigned i=2; i<5; i++)
        {
            TS_ASSERT_DELTA(vec_repl[3*i], 0.0, 1e-8);
            TS_ASSERT_DELTA(vec_repl[3*i], 0.0, 1e-8);
        }

        // node 5 is on the surface, and is an interior node
        TS_ASSERT_DELTA(vec_repl[15], 4*t1/6.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[16], 4*t2/6.0, 1e-8);


        // the rest of the vector is the pressure block and should be zero.
        TS_ASSERT_DELTA(vec_repl[2], 0.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[5], 0.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[8], 0.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[11], 0.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[14], 0.0, 1e-8);
        TS_ASSERT_DELTA(vec_repl[17], 0.0, 1e-8);

        PetscTools::Destroy(vec);
        PetscTools::Destroy(bad_sized_vec);
    }
Esempio n. 5
0
// Similar to above but uses a compressible material
unsigned SolvePressureOnUndersideCompressible(QuadraticMesh<3>& rMesh, std::string outputDirectory,
                                              std::vector<double>& rSolution,
                                              bool useSolutionAsGuess,
                                              double scaleFactor = 1.0)
{
    CompressibleExponentialLaw<3> law;
    std::vector<unsigned> fixed_nodes = NonlinearElasticityTools<3>::GetNodesByComponentValue(rMesh, 0, 0.0);

    std::vector<BoundaryElement<2,3>*> boundary_elems;

    double pressure = 0.001;

    for (TetrahedralMesh<3,3>::BoundaryElementIterator iter
           = rMesh.GetBoundaryElementIteratorBegin();
         iter != rMesh.GetBoundaryElementIteratorEnd();
         ++iter)
    {
        BoundaryElement<2,3>* p_element = *iter;
        double Z = p_element->CalculateCentroid()[2];
        if(fabs(Z)<1e-6)
        {
            boundary_elems.push_back(p_element);
        }
    }

    SolidMechanicsProblemDefinition<3> problem_defn(rMesh);
    problem_defn.SetMaterialLaw(COMPRESSIBLE,&law);
    problem_defn.SetZeroDisplacementNodes(fixed_nodes);

    problem_defn.SetApplyNormalPressureOnDeformedSurface(boundary_elems, pressure*scaleFactor);


    problem_defn.SetVerboseDuringSolve();

    CompressibleNonlinearElasticitySolver<3> solver(rMesh,problem_defn,outputDirectory);
    solver.SetWriteOutputEachNewtonIteration();

    // cover the SetTakeFullFirstNewtonStep() method, and the SetUsePetscDirectSolve() method
    solver.SetTakeFullFirstNewtonStep();
    solver.SetUsePetscDirectSolve();

    if(useSolutionAsGuess)
    {
        if(solver.rGetCurrentSolution().size()!=rSolution.size())
        {
            EXCEPTION("Badly-sized input");
        }
        for(unsigned i=0; i<rSolution.size(); i++)
        {
            solver.rGetCurrentSolution()[i] = rSolution[i];
        }
    }

    if(scaleFactor < 1.0)
    {
        try
        {
            solver.Solve();
        }
        catch (Exception& e)
        {
            // not final Solve, so don't quit
            WARNING(e.GetMessage());
        }
    }
    else
    {
        solver.Solve();
        solver.CreateCmguiOutput();
        
        VtkNonlinearElasticitySolutionWriter<3> vtk_writer(solver);
        vtk_writer.SetWriteElementWiseStrains(DEFORMATION_TENSOR_C);
        vtk_writer.Write();        
    }

    rSolution.clear();
    rSolution.resize(solver.rGetCurrentSolution().size());
    for(unsigned i=0; i<rSolution.size(); i++)
    {
        rSolution[i] = solver.rGetCurrentSolution()[i];
    }

    return solver.GetNumNewtonIterations();
}