opm-simulators/opm/core/tof/TofDiscGalReorder.hpp

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/*
Copyright 2012 SINTEF ICT, Applied Mathematics.
This file is part of the Open Porous Media project (OPM).
OPM is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OPM is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OPM. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef OPM_TOFDISCGALREORDER_HEADER_INCLUDED
#define OPM_TOFDISCGALREORDER_HEADER_INCLUDED
#include <opm/core/transport/reorder/ReorderSolverInterface.hpp>
#include <boost/shared_ptr.hpp>
#include <vector>
#include <map>
#include <ostream>
struct UnstructuredGrid;
namespace Opm
{
class IncompPropertiesInterface;
class VelocityInterpolationInterface;
class DGBasisInterface;
namespace parameter { class ParameterGroup; }
/// Implements a discontinuous Galerkin solver for
/// (single-phase) time-of-flight using reordering.
/// The equation solved is:
/// \f[v \cdot \nabla\tau = \phi\f]
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/// in which \f$ v \f$ is the fluid velocity, \f$ \tau \f$ is time-of-flight and
/// \f$ \phi \f$ is the porosity. This is a boundary value problem, and
/// \f$ \tau \f$ is specified to be zero on all inflow boundaries.
/// The user may specify the polynomial degree of the basis function space
/// used, but only degrees 0 and 1 are supported so far.
class TofDiscGalReorder : public ReorderSolverInterface
{
public:
/// Construct solver.
/// \param[in] grid A 2d or 3d grid.
/// \param[in] param Parameters for the solver.
/// The following parameters are accepted (defaults):\n
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/// - \c dg_degree (0) -- Polynomial degree of basis functions.
/// - \c use_tensorial_basis (false) -- Use tensor-product basis, interpreting dg_degree as
/// bi/tri-degree not total degree.
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/// - \c use_cvi (false) -- Use ECVI velocity interpolation.
/// - \c use_limiter (false) -- Use a slope limiter. If true, the next three parameters are used.
/// - \c limiter_relative_flux_threshold (1e-3) -- Ignore upstream fluxes below this threshold,
/// relative to total cell flux.
/// - \c limiter_method ("MinUpwindFace") -- Limiter method used. Accepted methods are:
/// - MinUpwindFace -- Limit cell tof to >= inflow face tofs.
/// - MinUpwindAverage -- Limit cell tof to >= inflow cell average tofs.
/// - \c limiter_usage ("DuringComputations") -- Usage pattern for limiter. Accepted choices are:
/// - DuringComputations -- Apply limiter to cells as they are computed,
/// so downstream cells' solutions may be affected
/// by limiting in upstream cells.
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/// - AsPostProcess -- Apply in dependency order, but only after
/// computing (unlimited) solution.
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/// - AsSimultaneousPostProcess -- Apply to each cell independently, using un-
/// limited solution in neighbouring cells.
TofDiscGalReorder(const UnstructuredGrid& grid,
const parameter::ParameterGroup& param);
/// Solve for time-of-flight.
/// \param[in] darcyflux Array of signed face fluxes.
/// \param[in] porevolume Array of pore volumes.
/// \param[in] source Source term. Sign convention is:
/// (+) inflow flux,
/// (-) outflow flux.
/// \param[out] tof_coeff Array of time-of-flight solution coefficients.
/// The values are ordered by cell, meaning that
/// the K coefficients corresponding to the first
/// cell comes before the K coefficients corresponding
/// to the second cell etc.
/// K depends on degree and grid dimension.
void solveTof(const double* darcyflux,
const double* porevolume,
const double* source,
std::vector<double>& tof_coeff);
private:
virtual void solveSingleCell(const int cell);
virtual void solveMultiCell(const int num_cells, const int* cells);
private:
// Disable copying and assignment.
TofDiscGalReorder(const TofDiscGalReorder&);
TofDiscGalReorder& operator=(const TofDiscGalReorder&);
// Data members
const UnstructuredGrid& grid_;
boost::shared_ptr<VelocityInterpolationInterface> velocity_interpolation_;
bool use_cvi_;
bool use_limiter_;
double limiter_relative_flux_threshold_;
enum LimiterMethod { MinUpwindFace, MinUpwindAverage };
LimiterMethod limiter_method_;
enum LimiterUsage { DuringComputations, AsPostProcess, AsSimultaneousPostProcess };
LimiterUsage limiter_usage_;
const double* darcyflux_; // one flux per grid face
const double* porevolume_; // one volume per cell
const double* source_; // one volumetric source term per cell
boost::shared_ptr<DGBasisInterface> basis_func_;
double* tof_coeff_;
std::vector<double> rhs_; // single-cell right-hand-side
std::vector<double> jac_; // single-cell jacobian
std::vector<double> orig_rhs_; // single-cell right-hand-side (copy)
std::vector<double> orig_jac_; // single-cell jacobian (copy)
// Below: storage for quantities needed by solveSingleCell().
std::vector<double> coord_;
mutable std::vector<double> basis_;
mutable std::vector<double> basis_nb_;
std::vector<double> grad_basis_;
std::vector<double> velocity_;
// Private methods
// Apply some limiter, writing to array tof
// (will read data from tof_coeff_, it is ok to call
// with tof_coeff as tof argument.
void applyLimiter(const int cell, double* tof);
void applyMinUpwindLimiter(const int cell, const bool face_min, double* tof);
void applyLimiterAsPostProcess();
void applyLimiterAsSimultaneousPostProcess();
double totalFlux(const int cell) const;
double minCornerVal(const int cell, const int face) const;
};
} // namespace Opm
#endif // OPM_TRANSPORTMODELTRACERTOFDISCGAL_HEADER_INCLUDED