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583 lines
24 KiB
C++
583 lines
24 KiB
C++
/*
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Copyright 2013, 2015 SINTEF ICT, Applied Mathematics.
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Copyright 2014, 2015 Statoil ASA.
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Copyright 2014, 2015 Dr. Markus Blatt - HPC-Simulation-Software & Services
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Copyright 2015 NTNU
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This file is part of the Open Porous Media project (OPM).
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OPM is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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OPM is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with OPM. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef OPM_BLACKOILMODELBASE_HEADER_INCLUDED
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#define OPM_BLACKOILMODELBASE_HEADER_INCLUDED
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#include <cassert>
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#include <opm/autodiff/AutoDiffBlock.hpp>
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#include <opm/autodiff/AutoDiffHelpers.hpp>
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#include <opm/autodiff/BlackoilPropsAdFromDeck.hpp>
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#include <opm/autodiff/LinearisedBlackoilResidual.hpp>
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#include <opm/autodiff/NewtonIterationBlackoilInterface.hpp>
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#include <opm/autodiff/BlackoilModelEnums.hpp>
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#include <opm/autodiff/VFPProperties.hpp>
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#include <opm/autodiff/RateConverter.hpp>
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#include <opm/autodiff/IterationReport.hpp>
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#include <opm/autodiff/DefaultBlackoilSolutionState.hpp>
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#include <opm/parser/eclipse/EclipseState/Grid/NNC.hpp>
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#include <opm/simulators/timestepping/SimulatorTimerInterface.hpp>
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#include <opm/core/simulator/SimulatorReport.hpp>
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#include <opm/common/data/SimulationDataContainer.hpp>
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#include <array>
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struct Wells;
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namespace Opm {
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class ParameterGroup;
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class DerivedGeology;
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class RockCompressibility;
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class NewtonIterationBlackoilInterface;
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class VFPProperties;
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/// Traits to encapsulate the types used by classes using or
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/// extending this model. Forward declared here, must be
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/// specialised for each concrete model class.
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template <class ConcreteModel>
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struct ModelTraits;
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/// A model implementation for three-phase black oil.
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///
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/// The simulator is capable of handling three-phase problems
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/// where gas can be dissolved in oil and vice versa. It
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/// uses an industry-standard TPFA discretization with per-phase
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/// upwind weighting of mobilities.
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///
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/// It uses automatic differentiation via the class AutoDiffBlock
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/// to simplify assembly of the jacobian matrix.
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/// \tparam Grid UnstructuredGrid or CpGrid.
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/// \tparam WellModel WellModel employed.
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/// \tparam Implementation Provides concrete state types.
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template<class Grid, class WellModel, class Implementation>
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class BlackoilModelBase
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{
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public:
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// --------- Types and enums ---------
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typedef AutoDiffBlock<double> ADB;
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typedef ADB::V V;
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typedef ADB::M M;
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struct ReservoirResidualQuant {
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ReservoirResidualQuant();
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std::vector<ADB> accum; // Accumulations
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ADB mflux; // Mass flux (surface conditions)
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ADB b; // Reciprocal FVF
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ADB mu; // Viscosities
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ADB rho; // Densities
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ADB kr; // Permeabilities
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ADB dh; // Pressure drop across int. interfaces
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ADB mob; // Phase mobility (per cell)
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};
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struct SimulatorData : public Opm::FIPDataEnums {
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SimulatorData(int num_phases);
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using Opm::FIPDataEnums :: FipId ;
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using Opm::FIPDataEnums :: fipValues ;
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std::vector<ReservoirResidualQuant> rq;
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ADB rsSat; // Saturated gas-oil ratio
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ADB rvSat; // Saturated oil-gas ratio
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std::vector<double> soMax; // Maximum oil saturation
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std::vector<double> Pb; // Bubble point pressure
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std::vector<double> Pd; // Dew point pressure
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//Hysteresis parameters
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std::vector<double> krnswdc_ow;
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std::vector<double> krnswdc_go;
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std::vector<double> pcswmdc_ow;
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std::vector<double> pcswmdc_go;
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std::array<V, fipValues> fip;
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};
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typedef Opm::FIPData FIPDataType;
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typedef typename ModelTraits<Implementation>::ReservoirState ReservoirState;
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typedef typename ModelTraits<Implementation>::WellState WellState;
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typedef typename ModelTraits<Implementation>::ModelParameters ModelParameters;
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typedef typename ModelTraits<Implementation>::SolutionState SolutionState;
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// For the conversion between the surface volume rate and resrevoir voidage rate
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using RateConverterType = RateConverter::
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SurfaceToReservoirVoidage<BlackoilPropsAdFromDeck::FluidSystem, std::vector<int> >;
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// --------- Public methods ---------
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/// Construct the model. It will retain references to the
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/// arguments of this functions, and they are expected to
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/// remain in scope for the lifetime of the solver.
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/// \param[in] param parameters
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/// \param[in] grid grid data structure
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/// \param[in] fluid fluid properties
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/// \param[in] geo rock properties
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/// \param[in] rock_comp_props if non-null, rock compressibility properties
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/// \param[in] wells well structure
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/// \param[in] vfp_properties Vertical flow performance tables
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/// \param[in] linsolver linear solver
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/// \param[in] eclState eclipse state
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/// \param[in] has_disgas turn on dissolved gas
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/// \param[in] has_vapoil turn on vaporized oil feature
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/// \param[in] terminal_output request output to cout/cerr
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BlackoilModelBase(const ModelParameters& param,
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const Grid& grid ,
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const BlackoilPropsAdFromDeck& fluid,
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const DerivedGeology& geo ,
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const RockCompressibility* rock_comp_props,
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const WellModel& well_model,
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const NewtonIterationBlackoilInterface& linsolver,
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std::shared_ptr< const EclipseState > eclState,
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std::shared_ptr< const Schedule> schedule,
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std::shared_ptr< const SummaryConfig> summary_config,
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const bool has_disgas,
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const bool has_vapoil,
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const bool terminal_output);
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/// \brief Set threshold pressures that prevent or reduce flow.
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/// This prevents flow across faces if the potential
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/// difference is less than the threshold. If the potential
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/// difference is greater, the threshold value is subtracted
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/// before calculating flow. This is treated symmetrically, so
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/// flow is prevented or reduced in both directions equally.
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/// \param[in] threshold_pressures_by_face array of size equal to the number of faces
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/// of the grid passed in the constructor.
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void setThresholdPressures(const std::vector<double>& threshold_pressures_by_face);
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/// Called once before each time step.
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/// \param[in] timer simulation timer
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/// \param[in, out] reservoir_state reservoir state variables
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/// \param[in, out] well_state well state variables
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void prepareStep(const SimulatorTimerInterface& timer,
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const ReservoirState& reservoir_state,
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const WellState& well_state);
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/// Called once per nonlinear iteration.
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/// This model will perform a Newton-Raphson update, changing reservoir_state
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/// and well_state. It will also use the nonlinear_solver to do relaxation of
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/// updates if necessary.
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/// \param[in] iteration should be 0 for the first call of a new timestep
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/// \param[in] timer simulation timer
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/// \param[in] nonlinear_solver nonlinear solver used (for oscillation/relaxation control)
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/// \param[in, out] reservoir_state reservoir state variables
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/// \param[in, out] well_state well state variables
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template <class NonlinearSolverType>
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SimulatorReport nonlinearIteration(const int iteration,
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const SimulatorTimerInterface& timer,
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NonlinearSolverType& nonlinear_solver,
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ReservoirState& reservoir_state,
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WellState& well_state);
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/// Called once after each time step.
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/// In this class, this function does nothing.
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/// \param[in] timer simulation timer
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/// \param[in, out] reservoir_state reservoir state variables
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/// \param[in, out] well_state well state variables
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void afterStep(const SimulatorTimerInterface& timer,
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ReservoirState& reservoir_state,
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WellState& well_state);
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/// Assemble the residual and Jacobian of the nonlinear system.
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/// \param[in] reservoir_state reservoir state variables
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/// \param[in, out] well_state well state variables
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/// \param[in] initial_assembly pass true if this is the first call to assemble() in this timestep
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SimulatorReport
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assemble(const ReservoirState& reservoir_state,
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WellState& well_state,
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const bool initial_assembly);
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/// \brief Compute the residual norms of the mass balance for each phase,
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/// the well flux, and the well equation.
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/// \return a vector that contains for each phase the norm of the mass balance
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/// and afterwards the norm of the residual of the well flux and the well equation.
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std::vector<double> computeResidualNorms() const;
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/// \brief compute the relative change between to simulation states
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// \return || u^n+1 - u^n || / || u^n+1 ||
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double relativeChange( const SimulationDataContainer& previous, const SimulationDataContainer& current ) const;
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/// The size (number of unknowns) of the nonlinear system of equations.
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int sizeNonLinear() const;
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/// Number of linear iterations used in last call to solveJacobianSystem().
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int linearIterationsLastSolve() const;
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/// Solve the Jacobian system Jx = r where J is the Jacobian and
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/// r is the residual.
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V solveJacobianSystem() const;
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/// Apply an update to the primary variables, chopped if appropriate.
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/// \param[in] dx updates to apply to primary variables
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/// \param[in, out] reservoir_state reservoir state variables
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/// \param[in, out] well_state well state variables
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void updateState(const V& dx,
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ReservoirState& reservoir_state,
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WellState& well_state);
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/// Return true if this is a parallel run.
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bool isParallel() const;
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/// Return true if output to cout is wanted.
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bool terminalOutputEnabled() const;
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/// Compute convergence based on total mass balance (tol_mb) and maximum
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/// residual mass balance (tol_cnv).
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/// \param[in] timer simulation timer
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/// \param[in] iteration current iteration number
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bool getConvergence(const SimulatorTimerInterface& timer, const int iteration);
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/// The number of active fluid phases in the model.
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int numPhases() const;
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/// The number of active materials in the model.
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/// This should be equal to the number of material balance
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/// equations.
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int numMaterials() const;
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/// The name of an active material in the model.
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/// It is required that material_index < numMaterials().
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const std::string& materialName(int material_index) const;
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/// Update the scaling factors for mass balance equations
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void updateEquationsScaling();
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/// return the WellModel object
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WellModel& wellModel() { return well_model_; }
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const WellModel& wellModel() const { return well_model_; }
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/// Return reservoir simulation data (for output functionality)
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const SimulatorData& getSimulatorData(const SimulationDataContainer&) const {
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return sd_;
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}
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/// Return fluid-in-place data (for output functionality)
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FIPDataType getFIPData() const {
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return FIPDataType( sd_.fip );
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}
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/// Compute fluid in place.
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/// \param[in] ReservoirState
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/// \param[in] FIPNUM for active cells not global cells.
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/// \return fluid in place, number of fip regions, each region contains 5 values which are liquid, vapour, water, free gas and dissolved gas.
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std::vector<std::vector<double> >
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computeFluidInPlace(const ReservoirState& x,
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const std::vector<int>& fipnum);
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/// Function to compute the resevoir voidage for the production wells.
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/// TODO: Probably should go to well model, while we then have duplications there for two Well Models.
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/// With time, it looks like probably we will introduce a base class for Well Models.
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void computeWellVoidageRates(const ReservoirState& reservoir_state,
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const WellState& well_state,
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std::vector<double>& well_voidage_rates,
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std::vector<double>& voidage_conversion_coeffs);
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void applyVREPGroupControl(const ReservoirState& reservoir_state,
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WellState& well_state);
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/// return the statistics if the nonlinearIteration() method failed.
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///
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/// NOTE: for the flow_legacy simulator family this method is a stub, i.e. the
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/// failure report object will *not* contain any meaningful data.
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const SimulatorReport& failureReport() const
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{ return failureReport_; }
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protected:
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// --------- Types and enums ---------
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typedef Eigen::Array<double,
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Eigen::Dynamic,
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Eigen::Dynamic,
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Eigen::RowMajor> DataBlock;
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// --------- Data members ---------
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SimulatorReport failureReport_;
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const Grid& grid_;
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const BlackoilPropsAdFromDeck& fluid_;
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const DerivedGeology& geo_;
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const RockCompressibility* rock_comp_props_;
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VFPProperties vfp_properties_;
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const NewtonIterationBlackoilInterface& linsolver_;
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// For each canonical phase -> true if active
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const std::vector<bool> active_;
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// Size = # active phases. Maps active -> canonical phase indices.
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const std::vector<int> canph_;
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const std::vector<int> cells_; // All grid cells
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HelperOps ops_;
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const bool has_disgas_;
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const bool has_vapoil_;
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ModelParameters param_;
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bool use_threshold_pressure_;
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V threshold_pressures_by_connection_;
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mutable SimulatorData sd_;
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std::vector<PhasePresence> phaseCondition_;
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// Well Model
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WellModel well_model_;
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V isRs_;
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V isRv_;
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V isSg_;
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LinearisedBlackoilResidual residual_;
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/// \brief Whether we print something to std::cout
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bool terminal_output_;
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/// \brief The number of cells of the global grid.
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int global_nc_;
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V pvdt_;
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std::vector<std::string> material_name_;
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std::vector<std::vector<double>> residual_norms_history_;
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double current_relaxation_;
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V dx_old_;
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// rate converter between the surface volume rates and reservoir voidage rates
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RateConverterType rate_converter_;
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// --------- Protected methods ---------
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/// Access the most-derived class used for
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/// static polymorphism (CRTP).
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Implementation& asImpl()
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{
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return static_cast<Implementation&>(*this);
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}
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/// Access the most-derived class used for
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/// static polymorphism (CRTP).
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const Implementation& asImpl() const
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{
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return static_cast<const Implementation&>(*this);
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}
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/// return the Well struct in the WellModel
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const Wells& wells() const { return well_model_.wells(); }
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/// return true if wells are available in the reservoir
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bool wellsActive() const { return well_model_.wellsActive(); }
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/// return true if wells are available on this process
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bool localWellsActive() const { return well_model_.localWellsActive(); }
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void
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makeConstantState(SolutionState& state) const;
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SolutionState
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variableState(const ReservoirState& x,
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const WellState& xw) const;
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std::vector<V>
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variableStateInitials(const ReservoirState& x,
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const WellState& xw) const;
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void
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variableReservoirStateInitials(const ReservoirState& x,
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std::vector<V>& vars0) const;
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std::vector<int>
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variableStateIndices() const;
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SolutionState
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variableStateExtractVars(const ReservoirState& x,
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const std::vector<int>& indices,
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std::vector<ADB>& vars) const;
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void
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computeAccum(const SolutionState& state,
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const int aix );
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void
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assembleMassBalanceEq(const SolutionState& state);
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SimulatorReport
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solveWellEq(const std::vector<ADB>& mob_perfcells,
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const std::vector<ADB>& b_perfcells,
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const ReservoirState& reservoir_state,
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SolutionState& state,
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WellState& well_state);
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void
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addWellContributionToMassBalanceEq(const std::vector<ADB>& cq_s,
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const SolutionState& state,
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const WellState& xw);
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bool getWellConvergence(const int iteration);
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bool isVFPActive() const;
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std::vector<ADB>
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computePressures(const ADB& po,
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const ADB& sw,
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const ADB& so,
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const ADB& sg) const;
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V
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computeGasPressure(const V& po,
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const V& sw,
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const V& so,
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const V& sg) const;
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std::vector<ADB>
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computeRelPerm(const SolutionState& state) const;
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void
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computeMassFlux(const int actph ,
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const V& transi,
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const ADB& kr ,
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const ADB& mu ,
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const ADB& rho ,
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const ADB& p ,
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const SolutionState& state );
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void applyThresholdPressures(ADB& dp);
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ADB
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fluidViscosity(const int phase,
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const ADB& p ,
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const ADB& temp ,
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const ADB& rs ,
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const ADB& rv ,
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const std::vector<PhasePresence>& cond) const;
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ADB
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fluidReciprocFVF(const int phase,
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const ADB& p ,
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const ADB& temp ,
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const ADB& rs ,
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const ADB& rv ,
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const std::vector<PhasePresence>& cond) const;
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ADB
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fluidDensity(const int phase,
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const ADB& b,
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const ADB& rs,
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const ADB& rv) const;
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V
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fluidRsSat(const V& p,
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const V& so,
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const std::vector<int>& cells) const;
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ADB
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fluidRsSat(const ADB& p,
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const ADB& so,
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const std::vector<int>& cells) const;
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V
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fluidRvSat(const V& p,
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const V& so,
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const std::vector<int>& cells) const;
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ADB
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fluidRvSat(const ADB& p,
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const ADB& so,
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const std::vector<int>& cells) const;
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ADB
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poroMult(const ADB& p) const;
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ADB
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transMult(const ADB& p) const;
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const std::vector<PhasePresence>
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phaseCondition() const {return phaseCondition_;}
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void
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classifyCondition(const ReservoirState& state);
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/// update the primal variable for Sg, Rv or Rs. The Gas phase must
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/// be active to call this method.
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void
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updatePrimalVariableFromState(const ReservoirState& state);
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/// Update the phaseCondition_ member based on the primalVariable_ member.
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/// Also updates isRs_, isRv_ and isSg_;
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void
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updatePhaseCondFromPrimalVariable(const ReservoirState& state);
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// TODO: added since the interfaces of the function are different
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// TODO: for StandardWells and MultisegmentWells
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void
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computeWellConnectionPressures(const SolutionState& state,
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const WellState& well_state);
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|
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/// \brief Compute the reduction within the convergence check.
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/// \param[in] B A matrix with MaxNumPhases columns and the same number rows
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/// as the number of cells of the grid. B.col(i) contains the values
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/// for phase i.
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/// \param[in] tempV A matrix with MaxNumPhases columns and the same number rows
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|
/// as the number of cells of the grid. tempV.col(i) contains the
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|
/// values
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|
/// for phase i.
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/// \param[in] R A matrix with MaxNumPhases columns and the same number rows
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|
/// as the number of cells of the grid. B.col(i) contains the values
|
|
/// for phase i.
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|
/// \param[out] R_sum An array of size MaxNumPhases where entry i contains the sum
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|
/// of R for the phase i.
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/// \param[out] maxCoeff An array of size MaxNumPhases where entry i contains the
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|
/// maximum of tempV for the phase i.
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|
/// \param[out] B_avg An array of size MaxNumPhases where entry i contains the average
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|
/// of B for the phase i.
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|
/// \param[out] maxNormWell The maximum of the well flux equations for each phase.
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|
/// \param[in] nc The number of cells of the local grid.
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|
/// \return The total pore volume over all cells.
|
|
double
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|
convergenceReduction(const Eigen::Array<double, Eigen::Dynamic, Eigen::Dynamic>& B,
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|
const Eigen::Array<double, Eigen::Dynamic, Eigen::Dynamic>& tempV,
|
|
const Eigen::Array<double, Eigen::Dynamic, Eigen::Dynamic>& R,
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|
std::vector<double>& R_sum,
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|
std::vector<double>& maxCoeff,
|
|
std::vector<double>& B_avg,
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|
std::vector<double>& maxNormWell,
|
|
int nc) const;
|
|
|
|
/// Set up the group control related at the beginning of each time step
|
|
void
|
|
setupGroupControl(const ReservoirState& reservoir_state,
|
|
WellState& well_state);
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|
|
|
double dpMaxRel() const { return param_.dp_max_rel_; }
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|
double dbhpMaxRel() const {return param_.dbhp_max_rel_; }
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|
double dsMax() const { return param_.ds_max_; }
|
|
double drMaxRel() const { return param_.dr_max_rel_; }
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|
double maxResidualAllowed() const { return param_.max_residual_allowed_; }
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|
|
|
};
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} // namespace Opm
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#include "BlackoilModelBase_impl.hpp"
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#endif // OPM_BLACKOILMODELBASE_HEADER_INCLUDED
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