/// A functional, used to instantiate bounce-back nodes at the locations of the cylinder
void cylinderSetup( MultiBlockLattice2D<T,DESCRIPTOR>& lattice,
IncomprFlowParam<T> const& parameters,
OnLatticeBoundaryCondition2D<T,DESCRIPTOR>& boundaryCondition )
{
const plint nx = parameters.getNx();
const plint ny = parameters.getNy();
Box2D outlet(nx-1,nx-1, 1,ny-2);
// Create Velocity boundary conditions everywhere
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(0, nx-1, 0, 0) );
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(0, nx-1, ny-1, ny-1) );
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(0,0, 1,ny-2) );
// .. except on right boundary, where we prefer a fixed-pressure condition.
boundaryCondition.setPressureConditionOnBlockBoundaries (
lattice, outlet );
setBoundaryVelocity (
lattice, lattice.getBoundingBox(),
PoiseuilleVelocity<T>(parameters) );
setBoundaryDensity (
lattice, outlet,
ConstantDensity<T>(1.) );
initializeAtEquilibrium (
lattice, lattice.getBoundingBox(),
PoiseuilleVelocityAndDensity<T,DESCRIPTOR>(parameters) );
plint cx = nx/4;
plint cy = ny/2+2;
plint r = cy/4;
DotList2D cylinderShape;
for (plint iX=0; iX<nx; ++iX) {
for (plint iY=0; iY<ny; ++iY) {
if ( (iX-cx)*(iX-cx) + (iY-cy)*(iY-cy) < r*r ) {
cylinderShape.addDot(Dot2D(iX,iY));
}
}
}
defineDynamics(lattice, cylinderShape, new BounceBack<T,DESCRIPTOR>);
lattice.initialize();
}
/// A functional, used to instantiate bounce-back nodes at the locations of the cylinder
void cylinderSetup( BlockLatticeBase2D<T,DESCRIPTOR>& lattice,
IncomprFlowParam<T> const& parameters,
OnLatticeBoundaryCondition2D<T,DESCRIPTOR>& boundaryCondition )
{
const plint nx = parameters.getNx();
const plint ny = parameters.getNy();
Box2D outlet(nx-1,nx-1, 1, ny-2);
// Create Velocity boundary conditions everywhere
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(0, 0, 1, ny-2) );
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(0, nx-1, 0, 0) );
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(0, nx-1, ny-1, ny-1) );
// .. except on right boundary, where we prefer an outflow condition
// (zero velocity-gradient).
boundaryCondition.setVelocityConditionOnBlockBoundaries (
lattice, Box2D(nx-1, nx-1, 1, ny-2), boundary::outflow );
setBoundaryVelocity (
lattice, lattice.getBoundingBox(),
PoiseuilleVelocity<T>(parameters) );
setBoundaryDensity (
lattice, outlet,
ConstantDensity<T>(1.) );
initializeAtEquilibrium (
lattice, lattice.getBoundingBox(),
PoiseuilleVelocityAndDensity<T>(parameters) );
plint cx = nx/4;
plint cy = ny/2+2; // cy is slightly offset to avoid full symmetry,
// and to get a Von Karman Vortex street.
plint radius = cy/4;
defineDynamics(lattice, lattice.getBoundingBox(),
new CylinderShapeDomain2D<T>(cx,cy,radius),
new plb::BounceBack<T,DESCRIPTOR>);
lattice.initialize();
}
void cavitySetup( MultiBlockLattice2D<T,DESCRIPTOR>& lattice,
IncomprFlowParam<T> const& parameters,
OnLatticeBoundaryCondition2D<T,DESCRIPTOR>& boundaryCondition )
{
const plint nx = parameters.getNx();
const plint ny = parameters.getNy();
boundaryCondition.setVelocityConditionOnBlockBoundaries(lattice);
setBoundaryVelocity(lattice, lattice.getBoundingBox(), Array<T,2>(0.,0.) );
initializeAtEquilibrium(lattice, lattice.getBoundingBox(), 1., Array<T,2>(0.,0.) );
T u = parameters.getLatticeU();
setBoundaryVelocity(lattice, Box2D(1, nx-2, ny-1, ny-1), Array<T,2>(u,0.) );
initializeAtEquilibrium(lattice, Box2D(1, nx-2, ny-1, ny-1), 1., Array<T,2>(u,0.) );
lattice.initialize();
}
int main(int argc, char *argv[])
{
plbInit(&argc, &argv);
global::directories().setOutputDir("./tmp/");
//srand(global::mpi().getRank());
const double PI = 3.1415926535897932;
plint nx = 1200;
plint ny = 600;
const int maxIter = 1600000;
const int saveIter = 100;
const int statIter = 10;
double omega = 0.8;
double rho1 = 1;
double rho0 = 0;
BlockLattice2D<T,DESCRIPTOR> myFluid (nx, ny, new BGKdynamics<T,DESCRIPTOR>(omega));
OnLatticeBoundaryCondition2D<T,DESCRIPTOR>*
boundaryCondition = createLocalBoundaryCondition2D<T,DESCRIPTOR>();
boundaryCondition = createInterpBoundaryCondition2D<T,DESCRIPTOR>();
boundaryCondition->setVelocityConditionOnBlockBoundaries(myFluid);
setBoundaryVelocity(myFluid, myFluid.getBoundingBox(), Array<T,2>(0.,0.) );
initializeAtEquilibrium(myFluid, myFluid.getBoundingBox(), 1., Array<T,2>(0.,0.), 0. );
//myFluid2.periodicity().toggle(0,true);
std::cout<<"ok0"<<std::endl;
//setBoundaryVelocity(myFluid, Box2D(1, nx, ny-1, ny-1), Array<T,2>(10.,0.) );
//initializeAtEquilibrium(myFluid, Box2D(1, nx, ny-1, ny-1), 1., Array<T,2>(10.,0.), 0. );
//std::cout<<"ok1"<<std::endl;
myFluid.initialize();
//MultiParticleField2D<BulkParticleField2D<T,DESCRIPTOR> >* particles =0;
BulkParticleChunk2D<T,DESCRIPTOR> myParticleChunk(nx, ny);
BulkParticleField2D<T,DESCRIPTOR> myParticleField(nx, ny);
BulkParticle2D<T,DESCRIPTOR> myParticle1(1, 1, Array<T,2>(300-100,300), 0,
Array<T,2>(0.0, 0), 0.0, 20, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle2(2, 1, Array<T,2>(300+100*cos(2*PI/3),300+100*sin(2*PI/3)), 0,
Array<T,2>(-0.0*cos(2*PI/3), -0.0*sin(2*PI/3)), 0, 20, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle3(3, 1, Array<T,2>(300+100*cos(PI/3), 300+100*sin(PI/3)), 0,
Array<T,2>(-0.0*cos(PI/3), -0.0*sin(PI/3)), 0, 20, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle4(4, 1, Array<T,2>(300+100,300), 0,
Array<T,2>(-0.0, 0), 0.0, 30, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle5(5, 1, Array<T,2>(300+100*cos(5*PI/3),300+100*sin(5*PI/3)), 0,
Array<T,2>(-0.0*cos(5*PI/3), -0.0*sin(5*PI/3)),0, 20, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle6(6, 1, Array<T,2>(300+100*cos(4*PI/3),300+100*sin(4*PI/3)), 0,
Array<T,2>(-0.0*cos(4*PI/3), -0.0*sin(4*PI/3)),0, 20, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle7(7, 1, Array<T,2>(900-100,300), 0,
Array<T,2>(-0.0, 0), 0.0, 24.5, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle8(8, 1, Array<T,2>(900+100*cos(2*PI/3), 300+100*sin(2*PI/3)), 0,
Array<T,2>(-0.0*cos(2*PI/3), -0.0*sin(2*PI/3)), 0, 24.5, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle9(9, 1, Array<T,2>(900+100*cos(PI/3), 300+100*sin(PI/3)), 0,
Array<T,2>(-0.0*cos(PI/3), -0.0*sin(PI/3)), 0, 24.5, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle10(10,1,Array<T,2>(900+100,300), 0,
Array<T,2>(-0.0, 0), 0.0, 24.5, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle11(11,1,Array<T,2>(900+100*cos(4*PI/3),300+100*sin(4*PI/3)), 0,
Array<T,2>(-0.0*cos(4*PI/3), -0.0*sin(4*PI/3)),0, 24.5, 5);
BulkParticle2D<T,DESCRIPTOR> myParticle12(12,1,Array<T,2>(900+100*cos(5*PI/3),300+100*sin(5*PI/3)), 0,
Array<T,2>(-0.0*cos(5*PI/3), -0.0*sin(5*PI/3)),0, 24.5, 5);
movingLumen2D<T,DESCRIPTOR> myLumen1(13, 450, 750, 200, 250, Array<T,2> (0.,-0.05));
movingLumen2D<T,DESCRIPTOR> myLumen2(14, 450, 750, 350, 400, Array<T,2> (0., 0.05));
//BulkParticle2D<T,DESCRIPTOR> myParticle7(7, 2, Array<T,2>(300,50), 0,
// Array<T,2>(0,0.1),0, 30, 5);
//BulkParticle2D(plint id_, plint tag_, Array<T,2> const& position_, T AngularPosition_,
// Array<T,2> const& velocity_, T AngularVelocity_, T radius_, T density_);
myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle1);
myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle2);
myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle3);
myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle4);
myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle5);
myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle6);
myParticleChunk.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle7);
myParticleChunk.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle8);
myParticleChunk.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle9);
myParticleChunk.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle10);
myParticleChunk.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle11);
myParticleChunk.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle12);
myParticleChunk.rigidize();
//myParticleField.addParticle(Box2D(0,nx-1, 0,ny-1), &myParticle7);
for (plint iT=0; iT<maxIter; ++iT) {
std::cout<<"=====================Identify particles boundary links==================\n\n"<<std::endl;
for(plint i=0;i<myParticleChunk.particles.size(); i++){
Box2D myBox(myParticleChunk.particles[i]->getPosition()[0] - myParticleChunk.particles[i]->getRadius()*1.414,
myParticleChunk.particles[i]->getPosition()[0] + myParticleChunk.particles[i]->getRadius()*1.414,
myParticleChunk.particles[i]->getPosition()[1] - myParticleChunk.particles[i]->getRadius()*1.414,
myParticleChunk.particles[i]->getPosition()[1] + myParticleChunk.particles[i]->getRadius()*1.414);
myParticleChunk.particles[i]->computeBoundaryLinks(myBox);
//myParticleChunk.particles[i]->computeBoundaries(myBox);
Array<T,2> velocity = myParticleChunk.particles[i]->getVelocity();
Array<T,2> position = myParticleChunk.particles[i]->getPosition();
std::cout<<"Position="<<position[0]<<","<<position[1]<<std::endl;
std::cout<<"Velocity="<<velocity[0]<<","<<velocity[1]<<std::endl;
//system("PAUSE");
}
for(plint i=0;i<myParticleField.particles.size(); i++){
Box2D myBox(myParticleField.particles[i]->getPosition()[0] - myParticleField.particles[i]->getRadius()*1.414,
myParticleField.particles[i]->getPosition()[0] + myParticleField.particles[i]->getRadius()*1.414,
myParticleField.particles[i]->getPosition()[1] - myParticleField.particles[i]->getRadius()*1.414,
myParticleField.particles[i]->getPosition()[1] + myParticleField.particles[i]->getRadius()*1.414);
myParticleField.particles[i]->computeBoundaryLinks(myBox);
}
myLumen1.computeBoundaryLinks(myFluid.getBoundingBox());
myLumen2.computeBoundaryLinks(myFluid.getBoundingBox());
std::cout<<"=============================Collide and stream==========================\n\n"<<std::endl;
myFluid.collideAndStream();
std::cout<<"=============particle, movingObject, wall and fluid interaction=============\n\n"<<std::endl;
for(plint i=0;i<myParticleField.particles.size(); i++){
myParticleField.particles[i]->particleToParticle(myParticleField);
myParticleField.particles[i]->particleToChunk(myParticleChunk);
}
for(plint i=0;i<myParticleField.particles.size(); i++){
myParticleField.particles[i]->wallToParticle(myFluid);
}
for(plint i=0;i<myParticleField.particles.size(); i++){
myLumen1.objectToParticle(myParticleField.particles[i]);
myLumen2.objectToParticle(myParticleField.particles[i]);
}
myParticleChunk.fixedChunkToFluid(myFluid,&myParticleField);
//myParticleChunk.chunkToFluid(myFluid);
myParticleField.particleToFluidCoupling(myFluid);
myLumen1.objectToFluid(myFluid);
myLumen2.objectToFluid(myFluid);
std::cout<<"=============particle and movingObject advance=============================\n\n"<<std::endl;
if(iT<=2000){
myLumen1.advance();
myLumen2.advance();
}
if(iT==5000){
myLumen1.setVelocity(Array<T,2> (0., 0.07));
myLumen2.setVelocity(Array<T,2> (0.,-0.07));
}
if(iT>=5000 && iT<=7000){
myLumen1.advance();
myLumen2.advance();
}
myParticleChunk.advanceChunk(myFluid.getBoundingBox(), -1.);
myParticleField.advanceParticles(myFluid.getBoundingBox(), -1.);
//if(iT == 500)myParticleChunk.releaseParticle(2, &myParticleField);
ImageWriter<T> imageWriter("leeloo.map");
if(iT%10 == 0){
//imageWriter.writeScaledGif(createFileName("fluid_", iT, 6),
// *computeDensity(myFluid));
imageWriter.writeGif(createFileName("fluid_", iT, 6),
//*computeVelocityNorm(myFluid), 0, 1);
*computeVelocityComponent(myFluid,0), -0.1, 0.1);
}
}
}
