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4b66b0874e
Methods that returns the scaled critical gas (SGCR) saturation and the scaled critical gas in oil saturation (SOGCR) is added to BlackoilPropsAdFromDeck and BlackoilPropsAdInterface A test is added in test_boprops_ad and fluid.data is modified to make the test non trivial.
274 lines
12 KiB
C++
274 lines
12 KiB
C++
/*
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Copyright 2013 SINTEF ICT, Applied Mathematics.
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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_BLACKOILPROPSADINTERFACE_HEADER_INCLUDED
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#define OPM_BLACKOILPROPSADINTERFACE_HEADER_INCLUDED
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#include <opm/autodiff/AutoDiffBlock.hpp>
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#include <opm/core/props/BlackoilPhases.hpp>
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namespace Opm
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{
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/// This class is intended to present a fluid interface for
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/// three-phase black-oil that is easy to use with the AD-using
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/// simulators.
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///
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/// Most methods are available in two overloaded versions, one
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/// taking a constant vector and returning the same, and one
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/// taking an AD type and returning the same. Derivatives are not
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/// returned separately by any method, only implicitly with the AD
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/// version of the methods.
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class BlackoilPropsAdInterface
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{
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public:
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/// Virtual destructor for inheritance.
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virtual ~BlackoilPropsAdInterface();
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////////////////////////////
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// Rock interface //
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////////////////////////////
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/// \return D, the number of spatial dimensions.
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virtual int numDimensions() const = 0;
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/// \return N, the number of cells.
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virtual int numCells() const = 0;
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/// \return Array of N porosity values.
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virtual const double* porosity() const = 0;
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/// \return Array of ND^2 permeability values.
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/// The D^2 permeability values for a cell are organized as a matrix,
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/// which is symmetric (so ordering does not matter).
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virtual const double* permeability() const = 0;
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////////////////////////////
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// Fluid interface //
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////////////////////////////
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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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typedef std::vector<int> Cells;
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/// \return Number of active phases (also the number of components).
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virtual int numPhases() const = 0;
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/// \return Object describing the active phases.
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virtual PhaseUsage phaseUsage() const = 0;
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// ------ Canonical named indices for each phase ------
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/// Canonical named indices for each phase.
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enum PhaseIndex { Water = BlackoilPhases::Aqua, Oil = BlackoilPhases::Liquid,
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Gas = BlackoilPhases::Vapour,
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Aqua = BlackoilPhases::Aqua,
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Liquid = BlackoilPhases::Liquid,
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Vapour = BlackoilPhases::Vapour,
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MaxNumPhases = BlackoilPhases::MaxNumPhases};
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// ------ Density ------
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/// Densities of stock components at surface conditions.
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/// \param[in] phaseIdx
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n density values for phase given by phaseIdx.
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virtual V surfaceDensity(const int PhaseIdx, const Cells& cells) const = 0;
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// ------ Viscosity ------
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/// Water viscosity.
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/// \param[in] pw Array of n water pressure values.
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/// \param[in] T Array of n temperature values.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n viscosity values.
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virtual
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ADB muWat(const ADB& pw,
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const ADB& T,
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const Cells& cells) const = 0;
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/// Oil viscosity.
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/// \param[in] po Array of n oil pressure values.
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/// \param[in] T Array of n temperature values.
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/// \param[in] rs Array of n gas solution factor values.
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/// \param[in] cond Array of n objects, each specifying which phases are present with non-zero saturation in a cell.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n viscosity values.
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virtual
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ADB muOil(const ADB& po,
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const ADB& T,
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const ADB& rs,
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const std::vector<PhasePresence>& cond,
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const Cells& cells) const = 0;
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/// Gas viscosity.
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/// \param[in] pg Array of n gas pressure values.
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/// \param[in] T Array of n temperature values.
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/// \param[in] rv Array of n vapor oil/gas ratios.
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/// \param[in] cond Array of n objects, each specifying which phases are present with non-zero saturation in a cell.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n viscosity values.
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virtual
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ADB muGas(const ADB& pg,
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const ADB& T,
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const ADB& rv,
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const std::vector<PhasePresence>& cond,
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const Cells& cells) const = 0;
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// ------ Formation volume factor (b) ------
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/// Water formation volume factor.
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/// \param[in] pw Array of n water pressure values.
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/// \param[in] T Array of n temperature values.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n formation volume factor values.
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virtual
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ADB bWat(const ADB& pw,
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const ADB& T,
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const Cells& cells) const = 0;
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/// Oil formation volume factor.
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/// \param[in] po Array of n oil pressure values.
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/// \param[in] T Array of n temperature values.
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/// \param[in] rs Array of n gas solution factor values.
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/// \param[in] cond Array of n objects, each specifying which phases are present with non-zero saturation in a cell.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n formation volume factor values.
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virtual
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ADB bOil(const ADB& po,
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const ADB& T,
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const ADB& rs,
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const std::vector<PhasePresence>& cond,
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const Cells& cells) const = 0;
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/// Gas formation volume factor.
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/// \param[in] pg Array of n gas pressure values.
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/// \param[in] T Array of n temperature values.
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/// \param[in] rv Array of n vapor oil/gas ratios.
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/// \param[in] cond Array of n objects, each specifying which phases are present with non-zero saturation in a cell.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n formation volume factor values.
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virtual
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ADB bGas(const ADB& pg,
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const ADB& T,
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const ADB& rv,
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const std::vector<PhasePresence>& cond,
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const Cells& cells) const = 0;
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// ------ Rs bubble point curve ------
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/// Bubble point curve for Rs as function of oil pressure.
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/// \param[in] po Array of n oil pressure values.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n bubble point values for Rs.
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virtual
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ADB rsSat(const ADB& po,
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const Cells& cells) const = 0;
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/// Bubble point curve for Rs as function of oil pressure.
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/// \param[in] po Array of n oil pressure values.
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/// \param[in] so Array of n oil saturation values.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n bubble point values for Rs.
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virtual
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ADB rsSat(const ADB& po,
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const ADB& so,
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const Cells& cells) const = 0;
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// ------ Rv condensation curve ------
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/// Condensation curve for Rv as function of oil pressure.
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/// \param[in] po Array of n oil pressure values.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n condensation point values for Rv.
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virtual
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ADB rvSat(const ADB& po,
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const Cells& cells) const = 0;
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/// Condensation curve for Rv as function of oil pressure.
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/// \param[in] po Array of n oil pressure values.
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/// \param[in] so Array of n oil saturation values.
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/// \param[in] cells Array of n cell indices to be associated with the pressure values.
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/// \return Array of n condensation point values for Rv.
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virtual
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ADB rvSat(const ADB& po,
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const ADB& so,
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const Cells& cells) const = 0;
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// ------ Relative permeability ------
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/// Relative permeabilities for all phases.
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/// \param[in] sw Array of n water saturation values.
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/// \param[in] so Array of n oil saturation values.
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/// \param[in] sg Array of n gas saturation values.
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/// \param[in] cells Array of n cell indices to be associated with the saturation values.
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/// \return An std::vector with 3 elements, each an array of n relperm values,
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/// containing krw, kro, krg. Use PhaseIndex for indexing into the result.
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virtual
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std::vector<ADB> relperm(const ADB& sw,
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const ADB& so,
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const ADB& sg,
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const Cells& cells) const = 0;
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/// Capillary pressure for all phases.
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/// \param[in] sw Array of n water saturation values.
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/// \param[in] so Array of n oil saturation values.
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/// \param[in] sg Array of n gas saturation values.
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/// \param[in] cells Array of n cell indices to be associated with the saturation values.
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/// \return An std::vector with 3 elements, each an array of n capillary pressure values,
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/// containing the offsets for each p_g, p_o, p_w. The capillary pressure between
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/// two arbitrary phases alpha and beta is then given as p_alpha - p_beta.
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virtual
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std::vector<ADB> capPress(const ADB& sw,
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const ADB& so,
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const ADB& sg,
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const Cells& cells) const = 0;
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/// Saturation update for hysteresis behavior.
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/// \param[in] cells Array of n cell indices to be associated with the saturation values.
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virtual
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void updateSatHyst(const std::vector<double>& saturation,
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const std::vector<int>& cells) = 0;
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/// Update for max oil saturation.
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virtual
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void updateSatOilMax(const std::vector<double>& saturation) = 0;
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/// Obtain the scaled critical oil in gas saturation values.
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/// \param[in] cells Array of cell indices.
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/// \return Array of critical oil in gas saturaion values.
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virtual
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V scaledCriticalOilinGasSaturations(const Cells& cells) const = 0;
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/// Obtain the scaled critical gas saturation values.
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/// \param[in] cells Array of cell indices.
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/// \return Array of scaled critical gas saturaion values.
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virtual
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V scaledCriticalGasSaturations(const Cells& cells) const = 0;
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};
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} // namespace Opm
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#endif // OPM_BLACKOILPROPSADINTERFACE_HEADER_INCLUDED
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