/* This file is part of the OpenLB library
*
* Copyright (C) 2019 Adrian Kummerländer
* E-mail contact: info@openlb.net
* The most recent release of OpenLB can be downloaded at
*
*
* This program 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 2
* of the License, or (at your option) any later version.
*
* This program 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 this program; if not, write to the Free
* Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
* Boston, MA 02110-1301, USA.
*/
#ifndef REFINEMENT_COUPLER_2D_HH
#define REFINEMENT_COUPLER_2D_HH
#include "coupler2D.h"
#include "dynamics/lbHelpers.h"
namespace olb {
template class DESCRIPTOR>
T Coupler2D::getScalingFactor() const
{
return 4. - _coarse.getConverter().getLatticeRelaxationFrequency();
}
template class DESCRIPTOR>
T Coupler2D::getInvScalingFactor() const
{
return 1./getScalingFactor();
}
template class DESCRIPTOR>
const Vector& Coupler2D::getFineLatticeR(int y) const
{
return _fineLatticeR[y];
}
template class DESCRIPTOR>
const Vector& Coupler2D::getCoarseLatticeR(int y) const
{
return _coarseLatticeR[y];
}
template class DESCRIPTOR>
Coupler2D::Coupler2D(Grid2D& coarse, Grid2D& fine,
Vector origin, Vector extend):
_coarse(coarse),
_fine(fine),
_coarseSize(floor(extend.norm() / coarse.getConverter().getPhysDeltaX() + 0.5)+1),
_fineSize(2*_coarseSize-1),
_vertical(util::nearZero(extend[0])),
_physOrigin(_coarse.alignOriginToGrid(origin)),
_coarseLatticeR(_coarseSize),
_fineLatticeR(_fineSize)
{
OLB_ASSERT(util::nearZero(extend[0]) || util::nearZero(extend[1]), "Coupling is only implemented alongside unit vectors");
const auto& coarseGeometry = _coarse.getCuboidGeometry();
const auto& fineGeometry = _fine.getCuboidGeometry();
const T deltaX = _fine.getConverter().getPhysDeltaX();
const Vector stepPhysR = _vertical ? Vector {0, deltaX} : Vector {deltaX, 0};
for (int i=0; i < _fineSize; ++i) {
if (i % 2 == 0) {
coarseGeometry.getLatticeR(_physOrigin + i*stepPhysR, _coarseLatticeR[i/2]);
}
fineGeometry.getLatticeR(_physOrigin + i*stepPhysR, _fineLatticeR[i]);
}
}
template class DESCRIPTOR>
FineCoupler2D::FineCoupler2D(Grid2D& coarse, Grid2D& fine,
Vector origin, Vector extend):
Coupler2D(coarse, fine, origin, extend),
_c2f_rho(this->_coarseSize),
_c2f_u(this->_coarseSize, Vector(T{})),
_c2f_fneq(this->_coarseSize, Vector::q>(T{}))
{
OstreamManager clout(std::cout,"C2F");
const auto& coarseOrigin = this->getCoarseLatticeR(0);
const auto& fineOrigin = this->getFineLatticeR(0);
clout << "coarse origin: " << coarseOrigin[0] << " " << coarseOrigin[1] << " " << coarseOrigin[2] << std::endl;
clout << "fine origin: " << fineOrigin[0] << " " << fineOrigin[1] << " " << fineOrigin[2] << std::endl;
clout << "fine size: " << this->_fineSize << std::endl;
}
template class DESCRIPTOR>
void FineCoupler2D::store()
{
auto& coarseLattice = this->_coarse.getSuperLattice();
for (int y=0; y < this->_coarseSize; ++y) {
const auto pos = this->getCoarseLatticeR(y);
T rho{};
T u[2] {};
T fNeq[DESCRIPTOR::q] {};
Cell coarseCell;
coarseLattice.get(pos, coarseCell);
lbHelpers::computeRhoU(coarseCell, rho, u);
lbHelpers::computeFneq(coarseCell, fNeq, rho, u);
_c2f_rho[y] = Vector(rho);
_c2f_u[y] = Vector(u);
_c2f_fneq[y] = Vector::q>(fNeq);
}
}
template
Vector order2interpolation(const Vector& f0, const Vector& f1)
{
return 0.5 * (f0 + f1);
}
template
Vector order3interpolation(const std::vector>& data, int y, bool ascending)
{
if (ascending) {
return 3./8. * data[y] + 3./4. * data[y+1] - 1./8. * data[y+2];
}
else {
return 3./8. * data[y] + 3./4. * data[y-1] - 1./8. * data[y-2];
}
}
template
Vector order4interpolation(const std::vector>& data, int y)
{
return 9./16. * (data[y] + data[y+1]) - 1./16. * (data[y-1] + data[y+2]);
}
template class DESCRIPTOR>
void FineCoupler2D::interpolate()
{
auto& coarseLattice = this->_coarse.getSuperLattice();
for (int y=0; y < this->_coarseSize; ++y) {
Cell coarseCell;
coarseLattice.get(this->getCoarseLatticeR(y), coarseCell);
T rho{};
T u[2] {};
lbHelpers::computeRhoU(coarseCell, rho, u);
_c2f_rho[y] = order2interpolation(Vector(rho), _c2f_rho[y]);
_c2f_u[y] = order2interpolation(Vector(u), _c2f_u[y]);
T fNeq[DESCRIPTOR::q] {};
lbHelpers::computeFneq(coarseCell, fNeq, rho, u);
_c2f_fneq[y] = order2interpolation(Vector::q>(fNeq), _c2f_fneq[y]);
}
}
template class DESCRIPTOR>
void FineCoupler2D::couple()
{
const auto& coarseLattice = this->_coarse.getSuperLattice();
auto& fineLattice = this->_fine.getSuperLattice();
for (int y=0; y < this->_coarseSize; ++y) {
const auto& coarsePos = this->getCoarseLatticeR(y);
const auto& finePos = this->getFineLatticeR(2*y);
T fEq[DESCRIPTOR::q] {};
Cell coarseCell;
coarseLattice.get(coarsePos, coarseCell);
lbHelpers::computeFeq(coarseCell, fEq);
Cell cell;
fineLattice.get(finePos, cell);
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
cell[iPop] = fEq[iPop] + this->getScalingFactor() * _c2f_fneq[y][iPop];
}
fineLattice.set(finePos, cell);
}
for (int y=1; y < this->_coarseSize-2; ++y) {
const auto rho = order4interpolation(_c2f_rho, y);
const auto u = order4interpolation(_c2f_u, y);
const auto fneq = order4interpolation(_c2f_fneq, y);
const T uSqr = u*u;
const auto finePos = this->getFineLatticeR(1+2*y);
Cell fineCell;
fineLattice.get(finePos, fineCell);
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
fineCell[iPop] = lbHelpers::equilibrium(iPop, rho[0], u.data, uSqr) + this->getScalingFactor() * fneq[iPop];
}
fineLattice.set(finePos, fineCell);
}
{
const auto rho = order3interpolation(_c2f_rho, 0, true);
const auto u = order3interpolation(_c2f_u, 0, true);
const auto fneq = order3interpolation(_c2f_fneq, 0, true);
const T uSqr = u*u;
const auto& finePos = this->getFineLatticeR(1);
Cell fineCell;
fineLattice.get(finePos, fineCell);
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
fineCell[iPop] = lbHelpers::equilibrium(iPop, rho[0], u.data, uSqr) + this->getScalingFactor() * fneq[iPop];
}
fineLattice.set(finePos, fineCell);
}
{
const auto rho = order3interpolation(_c2f_rho, this->_coarseSize-1, false);
const auto u = order3interpolation(_c2f_u, this->_coarseSize-1, false);
const auto fneq = order3interpolation(_c2f_fneq, this->_coarseSize-1, false);
const T uSqr = u*u;
const auto& finePos = this->getFineLatticeR(this->_fineSize-2);
Cell fineCell;
fineLattice.get(finePos, fineCell);
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
fineCell[iPop] = lbHelpers::equilibrium(iPop, rho[0], u.data, uSqr) + this->getScalingFactor() * fneq[iPop];
}
fineLattice.set(finePos, fineCell);
}
}
template class DESCRIPTOR>
void computeRestrictedFneq(const SuperLattice2D& lattice,
Vector latticeR,
T restrictedFneq[DESCRIPTOR::q])
{
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
const auto neighbor = latticeR + Vector {0, DESCRIPTOR::c[iPop][0], DESCRIPTOR::c[iPop][1]};
Cell cell;
lattice.get(neighbor, cell);
T fNeq[DESCRIPTOR::q] {};
lbHelpers::computeFneq(cell, fNeq);
for (int jPop=0; jPop < DESCRIPTOR::q; ++jPop) {
restrictedFneq[jPop] += fNeq[jPop];
}
}
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
restrictedFneq[iPop] /= DESCRIPTOR::q;
}
}
template class DESCRIPTOR>
CoarseCoupler2D::CoarseCoupler2D(
Grid2D& coarse, Grid2D& fine,
Vector origin, Vector extend):
Coupler2D(coarse, fine, origin, extend)
{
OstreamManager clout(std::cout,"F2C");
const auto& coarseOrigin = this->getCoarseLatticeR(0);
const auto& fineOrigin = this->getFineLatticeR(0);
clout << "coarse origin: " << coarseOrigin[0] << " " << coarseOrigin[1] << " " << coarseOrigin[2] << std::endl;
clout << "fine origin: " << fineOrigin[0] << " " << fineOrigin[1] << " " << fineOrigin[2] << std::endl;
clout << "coarse size: " << this->_coarseSize << std::endl;
}
template class DESCRIPTOR>
void CoarseCoupler2D::couple()
{
const auto& fineLattice = this->_fine.getSuperLattice();
auto& coarseLattice = this->_coarse.getSuperLattice();
for (int y=0; y < this->_coarseSize; ++y) {
const auto& finePos = this->getFineLatticeR(2*y);
const auto& coarsePos = this->getCoarseLatticeR(y);
T fEq[DESCRIPTOR::q] {};
Cell fineCell;
fineLattice.get(finePos, fineCell);
lbHelpers::computeFeq(fineCell, fEq);
T fNeq[DESCRIPTOR::q] {};
computeRestrictedFneq(fineLattice, finePos, fNeq);
Cell coarseCell;
coarseLattice.get(coarsePos, coarseCell);
for (int iPop=0; iPop < DESCRIPTOR::q; ++iPop) {
coarseCell[iPop] = fEq[iPop] + this->getInvScalingFactor() * fNeq[iPop];
}
coarseLattice.set(coarsePos, coarseCell);
}
}
}
#endif