opm-simulators/opm/core/utility/initState_impl.hpp

596 lines
27 KiB
C++

/*
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_INITSTATE_IMPL_HEADER_INCLUDED
#define OPM_INITSTATE_IMPL_HEADER_INCLUDED
#include <opm/core/utility/parameters/ParameterGroup.hpp>
#include <opm/core/grid.h>
#include <opm/core/eclipse/EclipseGridParser.hpp>
#include <opm/core/utility/ErrorMacros.hpp>
#include <opm/core/utility/MonotCubicInterpolator.hpp>
#include <opm/core/utility/Units.hpp>
#include <opm/core/fluid/IncompPropertiesInterface.hpp>
#include <opm/core/fluid/BlackoilPropertiesInterface.hpp>
#include <cmath>
namespace Opm
{
namespace
{
// Find the cells that are below and above a depth.
// TODO: add 'anitialiasing', obtaining a more precise split
// by f. ex. subdividing cells cut by the split depths.
void cellsBelowAbove(const UnstructuredGrid& grid,
const double depth,
std::vector<int>& below,
std::vector<int>& above)
{
const int num_cells = grid.number_of_cells;
below.reserve(num_cells);
above.reserve(num_cells);
const int dim = grid.dimensions;
for (int c = 0; c < num_cells; ++c) {
const double z = grid.cell_centroids[dim*c + dim - 1];
if (z > depth) {
below.push_back(c);
} else {
above.push_back(c);
}
}
}
enum WaterInit { WaterBelow, WaterAbove };
// Initialize saturations so that there is water below woc,
// and oil above.
// If invert is true, water is instead above, oil below.
template <class Props, class State>
void initWaterOilContact(const UnstructuredGrid& grid,
const Props& props,
const double woc,
const WaterInit waterinit,
State& state)
{
// Find out which cells should have water and which should have oil.
std::vector<int> water;
std::vector<int> oil;
// Assuming that water should go below the woc, but warning if oil is heavier.
// if (props.density()[0] < props.density()[1]) {
// std::cout << "*** warning: water density is less than oil density, "
// "but initialising water below woc." << std::endl;
// }
switch (waterinit) {
case WaterBelow:
cellsBelowAbove(grid, woc, water, oil);
break;
case WaterAbove:
cellsBelowAbove(grid, woc, oil, water);
}
// Set saturations.
state.setFirstSat(oil, props, State::MinSat);
state.setFirstSat(water, props, State::MaxSat);
}
// Initialize hydrostatic pressures depending only on gravity,
// (constant) phase densities and a water-oil contact depth.
// The pressure difference between points is equal to
// delta_p = delta_z * gravity * rho
// where rho is the (assumed constant) oil density above the
// woc, water density below woc.
// Note that even if there is (immobile) water in the oil zone,
// it does not contribute to the pressure difference.
// Note that by manipulating the densities parameter,
// it is possible to initialise with water on top instead of
// on the bottom etc.
template <class State>
void initHydrostaticPressure(const UnstructuredGrid& grid,
const double* densities,
const double woc,
const double gravity,
const double datum_z,
const double datum_p,
State& state)
{
std::vector<double>& p = state.pressure();
const int num_cells = grid.number_of_cells;
const int dim = grid.dimensions;
// Compute pressure at woc
const double rho_datum = datum_z > woc ? densities[0] : densities[1];
const double woc_p = datum_p + (woc - datum_z)*gravity*rho_datum;
for (int c = 0; c < num_cells; ++c) {
// Compute pressure as delta from woc pressure.
const double z = grid.cell_centroids[dim*c + dim - 1];
const double rho = z > woc ? densities[0] : densities[1];
p[c] = woc_p + (z - woc)*gravity*rho;
}
}
// Facade to initHydrostaticPressure() taking a property object,
// for similarity to initHydrostaticPressure() for compressible fluids.
template <class State>
void initHydrostaticPressure(const UnstructuredGrid& grid,
const IncompPropertiesInterface& props,
const double woc,
const double gravity,
const double datum_z,
const double datum_p,
State& state)
{
const double* densities = props.density();
initHydrostaticPressure(grid, densities, woc, gravity, datum_z, datum_p, state);
}
// Helper functor for initHydrostaticPressure() for compressible fluids.
struct Density
{
const BlackoilPropertiesInterface& props_;
Density(const BlackoilPropertiesInterface& props) : props_(props) {}
double operator()(const double pressure, const int phase)
{
ASSERT(props_.numPhases() == 2);
const double surfvol[2][2] = { { 1.0, 0.0 },
{ 0.0, 1.0 } };
// We do not handle multi-region PVT/EQUIL at this point.
const int* cells = 0;
double A[4] = { 0.0 };
props_.matrix(1, &pressure, surfvol[phase], cells, A, 0);
double rho[2] = { 0.0 };
props_.density(1, A, rho);
return rho[phase];
}
};
// Initialize hydrostatic pressures depending only on gravity,
// phase densities that may vary with pressure and a water-oil
// contact depth. The pressure ODE is given as
// \grad p = \rho g \grad z
// where rho is the oil density above the woc, water density
// below woc. Note that even if there is (immobile) water in
// the oil zone, it does not contribute to the pressure there.
template <class State>
void initHydrostaticPressure(const UnstructuredGrid& grid,
const BlackoilPropertiesInterface& props,
const double woc,
const double gravity,
const double datum_z,
const double datum_p,
State& state)
{
ASSERT(props.numPhases() == 2);
// Obtain max and min z for which we will need to compute p.
const int num_cells = grid.number_of_cells;
const int dim = grid.dimensions;
double zlim[2] = { 1e100, -1e100 };
for (int c = 0; c < num_cells; ++c) {
const double z = grid.cell_centroids[dim*c + dim - 1];
zlim[0] = std::min(zlim[0], z);
zlim[1] = std::max(zlim[1], z);
}
// We'll use a minimum stepsize of 1/100 of the z range.
const double hmin = (zlim[1] - zlim[0])/100.0;
// Store p(z) results in an associative array.
std::map<double, double> press_by_z;
press_by_z[datum_z] = datum_p;
// Set up density evaluator.
Density rho(props);
// Solve the ODE from datum_z to woc.
int phase = (datum_z > woc) ? 0 : 1;
int num_steps = int(std::ceil(std::fabs(woc - datum_z)/hmin));
double pval = datum_p;
double zval = datum_z;
double h = (woc - datum_z)/double(num_steps);
for (int i = 0; i < num_steps; ++i) {
zval += h;
const double dp = rho(pval, phase)*gravity;
pval += h*dp;
press_by_z[zval] = pval;
}
double woc_p = pval;
// Solve the ODE from datum_z to the end of the interval.
double z_end = (datum_z > woc) ? zlim[1] : zlim[0];
num_steps = int(std::ceil(std::fabs(z_end - datum_z)/hmin));
pval = datum_p;
zval = datum_z;
h = (z_end - datum_z)/double(num_steps);
for (int i = 0; i < num_steps; ++i) {
zval += h;
const double dp = rho(pval, phase)*gravity;
pval += h*dp;
press_by_z[zval] = pval;
}
// Solve the ODE from woc to the other end of the interval.
// Switching phase and z_end.
phase = (phase + 1) % 2;
z_end = (datum_z > woc) ? zlim[0] : zlim[1];
pval = woc_p;
zval = woc;
h = (z_end - datum_z)/double(num_steps);
for (int i = 0; i < num_steps; ++i) {
zval += h;
const double dp = rho(pval, phase)*gravity;
pval += h*dp;
press_by_z[zval] = pval;
}
// Create monotone spline for interpolating solution.
std::vector<double> zv, pv;
zv.reserve(press_by_z.size());
pv.reserve(press_by_z.size());
for (std::map<double, double>::const_iterator it = press_by_z.begin();
it != press_by_z.end(); ++it) {
zv.push_back(it->first);
pv.push_back(it->second);
}
MonotCubicInterpolator press(zv, pv);
// Evaluate pressure at each cell centroid.
std::vector<double>& p = state.pressure();
for (int c = 0; c < num_cells; ++c) {
const double z = grid.cell_centroids[dim*c + dim - 1];
p[c] = press(z);
}
}
// Initialize face pressures to distance-weighted average of adjacent cell pressures.
template <class State>
void initFacePressure(const UnstructuredGrid& grid,
State& state)
{
const int dim = grid.dimensions;
const std::vector<double>& cp = state.pressure();
std::vector<double>& fp = state.facepressure();
for (int f = 0; f < grid.number_of_faces; ++f) {
double dist[2] = { 0.0, 0.0 };
double press[2] = { 0.0, 0.0 };
int bdy_idx = -1;
for (int j = 0; j < 2; ++j) {
const int c = grid.face_cells[2*f + j];
if (c >= 0) {
dist[j] = 0.0;
for (int dd = 0; dd < dim; ++dd) {
double diff = grid.face_centroids[dim*f + dd] - grid.cell_centroids[dim*c + dd];
dist[j] += diff*diff;
}
dist[j] = std::sqrt(dist[j]);
press[j] = cp[c];
} else {
bdy_idx = j;
}
}
if (bdy_idx == -1) {
fp[f] = press[0]*(dist[1]/(dist[0] + dist[1])) + press[1]*(dist[0]/(dist[0] + dist[1]));
} else {
fp[f] = press[(bdy_idx + 1) % 2];
}
}
}
} // anonymous namespace
/// Initialize a twophase state from parameters.
/// The following parameters are accepted (defaults):
/// convection_testcase (false) Water in the 'left' part of the grid.
/// ref_pressure (100) Initial pressure in bar for all cells
/// (if convection_testcase is true),
/// or pressure at woc depth.
/// segregation_testcase (false) Water above the woc instead of below.
/// water_oil_contact (none) Depth of water-oil contact (woc).
/// init_saturation (none) Initial water saturation for all cells.
/// If convection_testcase is true, the saturation is initialised
/// as indicated, and pressure is initialised to a constant value
/// ('ref_pressure').
/// If segregation_testcase is true, the saturation is initialised
/// as indicated, and pressure is initialised hydrostatically.
/// Otherwise we have 3 cases:
/// 1) If 'water_oil_contact' is given, saturation is initialised
/// accordingly.
/// 2) If 'water_oil_contact' is not given, but 'init_saturation'
/// is given, water saturation is set to that value everywhere.
/// 3) If neither are given, water saturation is set to minimum.
/// In all three cases, pressure is initialised hydrostatically.
/// In case 2) and 3), the depth of the first cell is used as reference depth.
template <class State>
void initStateBasic(const UnstructuredGrid& grid,
const IncompPropertiesInterface& props,
const parameter::ParameterGroup& param,
const double gravity,
State& state)
{
const int num_phases = props.numPhases();
if (num_phases != 2) {
THROW("initStateTwophaseBasic(): currently handling only two-phase scenarios.");
}
state.init(grid, num_phases);
const int num_cells = props.numCells();
// By default: initialise water saturation to minimum everywhere.
std::vector<int> all_cells(num_cells);
for (int i = 0; i < num_cells; ++i) {
all_cells[i] = i;
}
state.setFirstSat(all_cells, props, State::MinSat);
const bool convection_testcase = param.getDefault("convection_testcase", false);
const bool segregation_testcase = param.getDefault("segregation_testcase", false);
if (convection_testcase) {
// Initialise water saturation to max in the 'left' part.
std::vector<int> left_cells;
left_cells.reserve(num_cells/2);
const int *glob_cell = grid.global_cell;
const int* cd = grid.cartdims;
for (int cell = 0; cell < num_cells; ++cell) {
const int gc = glob_cell == 0 ? cell : glob_cell[cell];
bool left = (gc % cd[0]) < cd[0]/2;
if (left) {
left_cells.push_back(cell);
}
}
state.setFirstSat(left_cells, props, State::MaxSat);
const double init_p = param.getDefault("ref_pressure", 100)*unit::barsa;
std::fill(state.pressure().begin(), state.pressure().end(), init_p);
} else if (segregation_testcase) {
// Warn against error-prone usage.
if (gravity == 0.0) {
std::cout << "**** Warning: running gravity segregation scenario, but gravity is zero." << std::endl;
}
if (grid.cartdims[2] <= 1) {
std::cout << "**** Warning: running gravity segregation scenario, which expects nz > 1." << std::endl;
}
// Initialise water saturation to max *above* water-oil contact.
const double woc = param.get<double>("water_oil_contact");
initWaterOilContact(grid, props, woc, WaterAbove, state);
// Initialise pressure to hydrostatic state.
const double ref_p = param.getDefault("ref_pressure", 100)*unit::barsa;
double dens[2] = { props.density()[1], props.density()[0] };
initHydrostaticPressure(grid, dens, woc, gravity, woc, ref_p, state);
} else if (param.has("water_oil_contact")) {
// Warn against error-prone usage.
if (gravity == 0.0) {
std::cout << "**** Warning: running gravity convection scenario, but gravity is zero." << std::endl;
}
if (grid.cartdims[2] <= 1) {
std::cout << "**** Warning: running gravity convection scenario, which expects nz > 1." << std::endl;
}
// Initialise water saturation to max below water-oil contact.
const double woc = param.get<double>("water_oil_contact");
initWaterOilContact(grid, props, woc, WaterBelow, state);
// Initialise pressure to hydrostatic state.
const double ref_p = param.getDefault("ref_pressure", 100)*unit::barsa;
initHydrostaticPressure(grid, props.density(), woc, gravity, woc, ref_p, state);
} else if (param.has("init_saturation")) {
// Initialise water saturation to init_saturation parameter.
const double init_saturation = param.get<double>("init_saturation");
for (int cell = 0; cell < num_cells; ++cell) {
state.saturation()[2*cell] = init_saturation;
state.saturation()[2*cell + 1] = 1.0 - init_saturation;
}
// Initialise pressure to hydrostatic state.
const double ref_p = param.getDefault("ref_pressure", 100)*unit::barsa;
const double rho = props.density()[0]*init_saturation + props.density()[1]*(1.0 - init_saturation);
const double dens[2] = { rho, rho };
const double ref_z = grid.cell_centroids[0 + grid.dimensions - 1];
initHydrostaticPressure(grid, dens, ref_z, gravity, ref_z, ref_p, state);
} else {
// Use default: water saturation is minimum everywhere.
// Initialise pressure to hydrostatic state.
const double ref_p = param.getDefault("ref_pressure", 100)*unit::barsa;
const double rho = props.density()[1];
const double dens[2] = { rho, rho };
const double ref_z = grid.cell_centroids[0 + grid.dimensions - 1];
initHydrostaticPressure(grid, dens, ref_z, gravity, ref_z, ref_p, state);
}
// Finally, init face pressures.
initFacePressure(grid, state);
}
/// Initialize a blackoil state from parameters.
/// The following parameters are accepted (defaults):
/// convection_testcase (false) Water in the 'left' part of the grid.
/// ref_pressure (100) Initial pressure in bar for all cells
/// (if convection_testcase is true),
/// or pressure at woc depth.
/// water_oil_contact (none) Depth of water-oil contact (woc).
/// If convection_testcase is true, the saturation is initialised
/// as indicated, and pressure is initialised to a constant value
/// ('ref_pressure').
/// Otherwise we have 2 cases:
/// 1) If 'water_oil_contact' is given, saturation is initialised
/// accordingly.
/// 2) Water saturation is set to minimum.
/// In both cases, pressure is initialised hydrostatically.
/// In case 2), the depth of the first cell is used as reference depth.
template <class State>
void initStateBasic(const UnstructuredGrid& grid,
const BlackoilPropertiesInterface& props,
const parameter::ParameterGroup& param,
const double gravity,
State& state)
{
// TODO: Refactor to exploit similarity with IncompProp* case.
const int num_phases = props.numPhases();
if (num_phases != 2) {
THROW("initStateTwophaseBasic(): currently handling only two-phase scenarios.");
}
state.init(grid, num_phases);
const int num_cells = props.numCells();
// By default: initialise water saturation to minimum everywhere.
std::vector<int> all_cells(num_cells);
for (int i = 0; i < num_cells; ++i) {
all_cells[i] = i;
}
state.setFirstSat(all_cells, props, State::MinSat);
const bool convection_testcase = param.getDefault("convection_testcase", false);
if (convection_testcase) {
// Initialise water saturation to max in the 'left' part.
std::vector<int> left_cells;
left_cells.reserve(num_cells/2);
const int *glob_cell = grid.global_cell;
const int* cd = grid.cartdims;
for (int cell = 0; cell < num_cells; ++cell) {
const int gc = glob_cell == 0 ? cell : glob_cell[cell];
bool left = (gc % cd[0]) < cd[0]/2;
if (left) {
left_cells.push_back(cell);
}
}
state.setFirstSat(left_cells, props, State::MaxSat);
const double init_p = param.getDefault("ref_pressure", 100)*unit::barsa;
std::fill(state.pressure().begin(), state.pressure().end(), init_p);
} else if (param.has("water_oil_contact")) {
// Warn against error-prone usage.
if (gravity == 0.0) {
std::cout << "**** Warning: running gravity convection scenario, but gravity is zero." << std::endl;
}
if (grid.cartdims[2] <= 1) {
std::cout << "**** Warning: running gravity convection scenario, which expects nz > 1." << std::endl;
}
// Initialise water saturation to max below water-oil contact.
const double woc = param.get<double>("water_oil_contact");
initWaterOilContact(grid, props, woc, WaterBelow, state);
// Initialise pressure to hydrostatic state.
const double ref_p = param.getDefault("ref_pressure", 100)*unit::barsa;
initHydrostaticPressure(grid, props, woc, gravity, woc, ref_p, state);
} else {
// Use default: water saturation is minimum everywhere.
// Initialise pressure to hydrostatic state.
const double ref_p = param.getDefault("ref_pressure", 100)*unit::barsa;
const double ref_z = grid.cell_centroids[0 + grid.dimensions - 1];
const double woc = -1e100;
initHydrostaticPressure(grid, props, woc, gravity, ref_z, ref_p, state);
}
// Finally, init face pressures.
initFacePressure(grid, state);
}
/// Initialize a state from input deck.
/// If EQUIL is present:
/// - saturation is set according to the water-oil contact,
/// - pressure is set to hydrostatic equilibrium.
/// Otherwise:
/// - saturation is set according to SWAT,
/// - pressure is set according to PRESSURE.
template <class Props, class State>
void initStateFromDeck(const UnstructuredGrid& grid,
const Props& props,
const EclipseGridParser& deck,
const double gravity,
State& state)
{
const int num_phases = props.numPhases();
if (num_phases != 2) {
THROW("initStateFromDeck(): currently handling only two-phase scenarios.");
}
state.init(grid, num_phases);
if (deck.hasField("EQUIL")) {
// Set saturations depending on oil-water contact.
const EQUIL& equil= deck.getEQUIL();
if (equil.equil.size() != 1) {
THROW("No region support yet.");
}
const double woc = equil.equil[0].water_oil_contact_depth_;
initWaterOilContact(grid, props, woc, WaterBelow, state);
// Set pressure depending on densities and depths.
const double datum_z = equil.equil[0].datum_depth_;
const double datum_p = equil.equil[0].datum_depth_pressure_;
initHydrostaticPressure(grid, props, woc, gravity, datum_z, datum_p, state);
} else if (deck.hasField("SWAT") && deck.hasField("PRESSURE")) {
// Set saturations from SWAT, pressure from PRESSURE.
std::vector<double>& s = state.saturation();
std::vector<double>& p = state.pressure();
const std::vector<double>& sw_deck = deck.getFloatingPointValue("SWAT");
const std::vector<double>& p_deck = deck.getFloatingPointValue("PRESSURE");
const int num_cells = grid.number_of_cells;
for (int c = 0; c < num_cells; ++c) {
int c_deck = (grid.global_cell == NULL) ? c : grid.global_cell[c];
s[2*c] = sw_deck[c_deck];
s[2*c + 1] = 1.0 - s[2*c];
p[c] = p_deck[c_deck];
}
} else {
THROW("initStateFromDeck(): we must either have EQUIL, or both SWAT and PRESSURE.");
}
// Finally, init face pressures.
initFacePressure(grid, state);
}
/// Initialize surface volume from pressure and saturation by z = As.
template <class Props, class State>
void initBlackoilSurfvol(const UnstructuredGrid& grid,
const Props& props,
State& state)
{
state.surfacevol() = state.saturation();
const int np = props.numPhases();
const int nc = grid.number_of_cells;
std::vector<double> allA(nc*np*np);
std::vector<int> allcells(nc);
for (int c = 0; c < nc; ++c) {
allcells[c] = c;
}
// Assuming that using the saturation as z argument here does not change
// the outcome. This is not guaranteed unless we have only a single phase
// per cell.
props.matrix(nc, &state.pressure()[0], &state.surfacevol()[0], &allcells[0], &allA[0], 0);
for (int c = 0; c < nc; ++c) {
// Using z = As
double* z = &state.surfacevol()[c*np];
const double* s = &state.saturation()[c*np];
const double* A = &allA[c*np*np];
for (int row = 0; row < np; ++row) { z[row] = 0.0; }
for (int col = 0; col < np; ++col) {
for (int row = 0; row < np; ++row) {
// Recall: A has column-major ordering.
z[row] += A[row + np*col]*s[col];
}
}
}
}
} // namespace Opm
#endif // OPM_INITSTATE_IMPL_HEADER_INCLUDED