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/*!
* \file
*
* \brief The one-phase porousmediumflow problem for exercise mainfile
*/
#ifndef DUMUX_EX_MAINFILE_ONEP_TEST_PROBLEM_HH
#define DUMUX_EX_MAINFILE_ONEP_TEST_PROBLEM_HH
#include <dune/grid/yaspgrid.hh>
#include <dumux/material/components/simpleh2o.hh>
#include <dumux/material/components/h2o.hh>
#include <dumux/material/components/tabulatedcomponent.hh>
#include <dumux/material/fluidsystems/1pliquid.hh>
#include <dumux/discretization/cellcentered/tpfa/properties.hh>
#include <dumux/discretization/cellcentered/mpfa/properties.hh>
#include <dumux/discretization/box/properties.hh>
// TODO: dumux-course-task
// uncomment the incompressiblelocalresidual which is a specialization of the standard immisible localresidual for one phase incompressible cases and provides an analytic jacobian.
//#include <dumux/porousmediumflow/1p/incompressiblelocalresidual.hh>
#include <dumux/porousmediumflow/problem.hh>
#include <dumux/porousmediumflow/1p/model.hh>
#include "1pspatialparams.hh"
namespace Dumux
{
// forward declarations
template<class TypeTag> class OnePTestProblem;
namespace Properties
{
// create the type tag nodes. Here we define the incompressible type tag as well as the compressible type tag. The incompressible uses a different fluidsystem than the compressible
NEW_TYPE_TAG(OnePBase, INHERITS_FROM(OneP));
NEW_TYPE_TAG(OnePIncompressible, INHERITS_FROM(CCTpfaModel, OnePBase));
NEW_TYPE_TAG(OnePCompressible, INHERITS_FROM(CCTpfaModel, OnePBase));
// Set the grid type
SET_TYPE_PROP(OnePBase, Grid, Dune::YaspGrid<2>);
// Set the problem type
SET_TYPE_PROP(OnePBase, Problem, OnePTestProblem<TypeTag>);
// set the spatial params
SET_TYPE_PROP(OnePBase, SpatialParams, OnePTestSpatialParams<TypeTag>);
// the fluid system for incompressible tests
SET_PROP(OnePIncompressible, FluidSystem)
{
private:
using Scalar = typename GET_PROP_TYPE(TypeTag, Scalar);
public:
using type = FluidSystems::OnePLiquid<Scalar, Components::SimpleH2O<Scalar> >;
};
// TODO: dumux-course-task
// set the OneP Incompressible local residual for the OnePIncompressible type tag. This provides an analytic jacobian to be used for the analytic solution. Change that by setting:
//SET_TYPE_PROP(OnePIncompressible, LocalResidual, OnePIncompressibleLocalResidual<TypeTag>);
// the fluid system for compressible tests
SET_PROP(OnePCompressible, FluidSystem)
{
private:
using Scalar = typename GET_PROP_TYPE(TypeTag, Scalar);
public:
using type = FluidSystems::OnePLiquid<Scalar, Components::TabulatedComponent<Components::H2O<Scalar>>>;
};
// Disable caching (for testing purposes)
SET_BOOL_PROP(OnePBase, EnableGridVolumeVariablesCache, false);
SET_BOOL_PROP(OnePBase, EnableGridFluxVariablesCache, false);
SET_BOOL_PROP(OnePBase, EnableFVGridGeometryCache, false);
} // end namespace Properties
/*!
* \ingroup OnePTests
* \brief Test problem for the compressible one-phase model:
* \todo doc me!
* <tt>./test_box1pfv</tt> or
* <tt>./test_cc1pfv</tt>
*/
template<class TypeTag>
class OnePTestProblem : public PorousMediumFlowProblem<TypeTag>
{
using ParentType = PorousMediumFlowProblem<TypeTag>;
using GridView = typename GET_PROP_TYPE(TypeTag, GridView);
using Element = typename GridView::template Codim<0>::Entity;
using Scalar = typename GET_PROP_TYPE(TypeTag, Scalar);
using PrimaryVariables = typename GET_PROP_TYPE(TypeTag, PrimaryVariables);
using FVGridGeometry = typename GET_PROP_TYPE(TypeTag, FVGridGeometry);
using BoundaryTypes = typename GET_PROP_TYPE(TypeTag, BoundaryTypes);
static constexpr int dimWorld = GridView::dimensionworld;
using GlobalPosition = typename Element::Geometry::GlobalCoordinate;
public:
OnePTestProblem(std::shared_ptr<const FVGridGeometry> fvGridGeometry)
: ParentType(fvGridGeometry)
{}
/*!
* \brief Specifies which kind of boundary condition should be
* used for which equation on a given boundary control volume.
*
* \param values The boundary types for the conservation equations
* \param globalPos The position of the center of the finite volume
*/
BoundaryTypes boundaryTypesAtPos(const GlobalPosition &globalPos) const
{
BoundaryTypes values;
Scalar eps = 1.0e-6;
if (globalPos[dimWorld-1] < eps || globalPos[dimWorld-1] > this->fvGridGeometry().bBoxMax()[dimWorld-1] - eps)
values.setAllDirichlet();
else
values.setAllNeumann();
return values;
}
/*!
* \brief Evaluate the boundary conditions for a dirichlet
* control volume.
*
* \param values The dirichlet values for the primary variables
* \param globalPos The center of the finite volume which ought to be set.
*
* For this method, the \a values parameter stores primary variables.
*/
PrimaryVariables dirichletAtPos(const GlobalPosition &globalPos) const
{
PrimaryVariables values(0);
values[0] = 1.0e5*(2.0 - globalPos[dimWorld-1]);
return values;
}
/*!
* \brief Evaluate the initial conditions
*
* \param globalPos The center of the finite volume which ought to be set.
*/
PrimaryVariables initialAtPos(const GlobalPosition& globalPos) const
{
return PrimaryVariables(1.0e5);
}
/*!
* \brief Returns the temperature \f$\mathrm{[K]}\f$ for an isothermal problem.
*
* This is not specific to the discretization. By default it just
* throws an exception so it must be overloaded by the problem if
* no energy equation is used.
*/
Scalar temperature() const
{
return 283.15; // 10°C
}
};
} // end namespace Dumux
#endif