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/* Lattice Boltzmann sample, written in C++, using the OpenLB
* library
*
* Copyright (C) 2014 Mathias J. Krause, Thomas Henn,
* Cyril Masquelier
* E-mail contact: info@openlb.net
* The most recent release of OpenLB can be downloaded at
* <http://www.openlb.net/>
*
* 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.
*/
/* venturi3d.cpp:
* This example examines a steady flow in a venturi tube. At the
* main inlet, a Poiseuille profile is imposed as Dirichlet velocity
* boundary condition, whereas at the outlet and the minor inlet
* a Dirichlet pressure condition is set by p=0 (i.e. rho=1).
*
* The example shows the usage of the Indicator functors to
* build up a geometry and explains how to set boundary conditions
* automatically.
*/
#include "olb3D.h"
#ifndef OLB_PRECOMPILED // Unless precompiled version is used
#include "olb3D.hh" // Include full template code
#endif
#include <iostream>
#include <fstream>
using namespace olb;
using namespace olb::descriptors;
using namespace olb::graphics;
using namespace olb::util;
using namespace std;
typedef double T;
#define DESCRIPTOR D3Q19<>
T maxPhysT = 200.0; // max. simulation time in s, SI unit
SuperGeometry3D<T> prepareGeometry( ) {
OstreamManager clout( std::cout,"prepareGeometry" );
clout << "Prepare Geometry ..." << std::endl;
std::string fName("venturi3d.xml");
XMLreader config(fName);
std::shared_ptr<IndicatorF3D<T> > inflow = createIndicatorCylinder3D<T>(config["Geometry"]["Inflow"]["IndicatorCylinder3D"], false);
std::shared_ptr<IndicatorF3D<T> > outflow0 = createIndicatorCylinder3D<T>(config["Geometry"]["Outflow0"]["IndicatorCylinder3D"], false);
std::shared_ptr<IndicatorF3D<T> > outflow1 = createIndicatorCylinder3D<T>(config["Geometry"]["Outflow1"]["IndicatorCylinder3D"], false);
std::shared_ptr<IndicatorF3D<T> > venturi = createIndicatorF3D<T>(config["Geometry"]["Venturi"], false);
// Build CoboidGeometry from IndicatorF (weights are set, remove and shrink is done)
int N = config["Application"]["Discretization"]["Resolution"].get<int>();
CuboidGeometry3D<T>* cuboidGeometry = new CuboidGeometry3D<T>( *venturi, 1./N, 20*singleton::mpi().getSize() );
// Build LoadBalancer from CuboidGeometry (weights are respected)
HeuristicLoadBalancer<T>* loadBalancer = new HeuristicLoadBalancer<T>( *cuboidGeometry );
// Default instantiation of superGeometry
SuperGeometry3D<T> superGeometry( *cuboidGeometry, *loadBalancer, 2 );
// Set boundary voxels by rename material numbers
superGeometry.rename( 0,2, venturi );
superGeometry.rename( 2,1,1,1,1 );
superGeometry.rename( 2,3,1, inflow );
superGeometry.rename( 2,4,1, outflow0 );
superGeometry.rename( 2,5,1, outflow1 );
// Removes all not needed boundary voxels outside the surface
superGeometry.clean();
// Removes all not needed boundary voxels inside the surface
superGeometry.innerClean();
superGeometry.checkForErrors();
superGeometry.getStatistics().print();
superGeometry.communicate();
clout << "Prepare Geometry ... OK" << std::endl;
return superGeometry;
}
void prepareLattice( SuperLattice3D<T,DESCRIPTOR>& sLattice,
UnitConverter<T, DESCRIPTOR> const& converter,
Dynamics<T, DESCRIPTOR>& bulkDynamics,
sOnLatticeBoundaryCondition3D<T,DESCRIPTOR>& bc,
sOffLatticeBoundaryCondition3D<T,DESCRIPTOR>& offBc,
SuperGeometry3D<T>& superGeometry ) {
OstreamManager clout( std::cout,"prepareLattice" );
clout << "Prepare Lattice ..." << std::endl;
const T omega = converter.getLatticeRelaxationFrequency();
// Material=0 -->do nothing
sLattice.defineDynamics( superGeometry, 0, &instances::getNoDynamics<T, DESCRIPTOR>() );
// Material=1 -->bulk dynamics
sLattice.defineDynamics( superGeometry, 1, &bulkDynamics );
// Material=2 -->bounce back
sLattice.defineDynamics( superGeometry, 2, &instances::getBounceBack<T, DESCRIPTOR>() );
// Material=3 -->bulk dynamics (inflow)
sLattice.defineDynamics( superGeometry, 3, &bulkDynamics );
// Material=4 -->bulk dynamics (outflow)
sLattice.defineDynamics( superGeometry, 4, &bulkDynamics );
// Material=5 -->bulk dynamics (2nd outflow)
sLattice.defineDynamics( superGeometry, 5, &bulkDynamics );
// Setting of the boundary conditions
bc.addVelocityBoundary( superGeometry, 3, omega );
bc.addPressureBoundary( superGeometry, 4, omega );
bc.addPressureBoundary( superGeometry, 5, omega );
clout << "Prepare Lattice ... OK" << std::endl;
}
// Generates a slowly increasing sinuidal inflow for the first iTMax timesteps
void setBoundaryValues( SuperLattice3D<T, DESCRIPTOR>& sLattice,
UnitConverter<T, DESCRIPTOR> const& converter, int iT,
SuperGeometry3D<T>& superGeometry ) {
OstreamManager clout( std::cout,"setBoundaryValues" );
// No of time steps for smooth start-up
int iTmaxStart = converter.getLatticeTime( maxPhysT*0.8 );
int iTperiod = 50;
if ( iT==0 ) {
// Make the lattice ready for simulation
sLattice.initialize();
}
else if ( iT%iTperiod==0 && iT<= iTmaxStart ) {
//clout << "Set Boundary Values ..." << std::endl;
//SinusStartScale<T,int> startScale(iTmaxStart, (T) 1);
PolynomialStartScale<T,int> startScale( iTmaxStart, T( 1 ) );
int iTvec[1]= {iT};
T frac = T();
startScale( &frac,iTvec );
// Creates and sets the Poiseuille inflow profile using functors
CirclePoiseuille3D<T> poiseuilleU( superGeometry, 3, frac*converter.getCharLatticeVelocity(), converter.getConversionFactorLength() );
sLattice.defineU( superGeometry, 3, poiseuilleU );
//clout << "step=" << iT << "; scalingFactor=" << frac << std::endl;
}
//clout << "Set Boundary Values ... ok" << std::endl;
}
void getResults( SuperLattice3D<T, DESCRIPTOR>& sLattice,
UnitConverter<T, DESCRIPTOR>& converter, int iT,
SuperGeometry3D<T>& superGeometry, Timer<T>& timer ) {
OstreamManager clout( std::cout,"getResults" );
SuperVTMwriter3D<T> vtmWriter( "venturi3d" );
if ( iT==0 ) {
// Writes the geometry, cuboid no. and rank no. as vti file for visualization
SuperLatticeGeometry3D<T, DESCRIPTOR> geometry( sLattice, superGeometry );
SuperLatticeCuboid3D<T, DESCRIPTOR> cuboid( sLattice );
SuperLatticeRank3D<T, DESCRIPTOR> rank( sLattice );
vtmWriter.write( geometry );
vtmWriter.write( cuboid );
vtmWriter.write( rank );
vtmWriter.createMasterFile();
}
// Writes the vtm files
if ( iT%converter.getLatticeTime( 1. )==0 ) {
// Create the data-reading functors...
SuperLatticePhysVelocity3D<T, DESCRIPTOR> velocity( sLattice, converter );
SuperLatticePhysPressure3D<T, DESCRIPTOR> pressure( sLattice, converter );
vtmWriter.addFunctor( velocity );
vtmWriter.addFunctor( pressure );
vtmWriter.write( iT );
SuperEuklidNorm3D<T, DESCRIPTOR> normVel( velocity );
BlockReduction3D2D<T> planeReduction( normVel, {0, 0, 1} );
// write output as JPEG
heatmap::write(planeReduction, iT);
// write output as JPEG and changing properties
heatmap::plotParam<T> jpeg_Param;
jpeg_Param.name = "outflow";
jpeg_Param.contourlevel = 5;
jpeg_Param.colour = "blackbody";
jpeg_Param.zoomOrigin = {0.6, 0.3};
jpeg_Param.zoomExtend = {0.4, 0.7};
heatmap::write(planeReduction, iT, jpeg_Param);
}
// Writes output on the console
if ( iT%converter.getLatticeTime( 1. )==0 ) {
timer.update( iT );
timer.printStep();
sLattice.getStatistics().print( iT, converter.getPhysTime( iT ) );
}
}
int main( int argc, char* argv[] ) {
// === 1st Step: Initialization ===
olbInit( &argc, &argv );
singleton::directories().setOutputDir( "./tmp/" );
OstreamManager clout( std::cout,"main" );
// display messages from every single mpi process
// clout.setMultiOutput(true);
std::string fName("venturi3d.xml");
XMLreader config(fName);
UnitConverter<T, DESCRIPTOR>* converter = createUnitConverter<T, DESCRIPTOR>(config);
// Prints the converter log as console output
converter->print();
// Writes the converter log in a file
converter->
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