void runProgram() { /* * Read the obstacle geometry. */ pcout << std::endl << "Reading STL data for the obstacle geometry." << std::endl; Array<T,3> center(param.cx, param.cy, param.cz); Array<T,3> centerLB(param.cxLB, param.cyLB, param.czLB); // The triangle-set defines the surface of the geometry. TriangleSet<T> triangleSet(param.geometry_fname, DBL); // Place the obstacle in the correct place in the simulation domain. // Here the "geometric center" of the obstacle is computed manually, // by computing first its bounding cuboid. In cases that the STL // file with the geometry of the obstacle contains its center as // the point, say (0, 0, 0), then the following variable // "obstacleCenter" must be set to (0, 0, 0) manually. Cuboid<T> bCuboid = triangleSet.getBoundingCuboid(); Array<T,3> obstacleCenter = 0.5 * (bCuboid.lowerLeftCorner + bCuboid.upperRightCorner); triangleSet.translate(-obstacleCenter); triangleSet.scale(1.0/param.dx); // In lattice units from now on... triangleSet.translate(centerLB); triangleSet.writeBinarySTL(outputDir+"obstacle_LB.stl"); // The DEFscaledMesh, and the triangle-boundary are more sophisticated data // structures used internally by Palabos to treat the boundary. plint xDirection = 0; plint borderWidth = 1; // Because Guo acts in a one-cell layer. // Requirement: margin>=borderWidth. plint margin = 1; // Extra margin of allocated cells around the obstacle, for the case of moving walls. plint blockSize = 0; // Size of blocks in the sparse/parallel representation. // Zero means: don't use sparse representation. DEFscaledMesh<T> defMesh(triangleSet, 0, xDirection, margin, Dot3D(0, 0, 0)); TriangleBoundary3D<T> boundary(defMesh); //boundary.getMesh().inflate(); pcout << "tau = " << 1.0/param.omega << std::endl; pcout << "dx = " << param.dx << std::endl; pcout << "dt = " << param.dt << std::endl; pcout << "Number of iterations in an integral time scale: " << (plint) (1.0/param.dt) << std::endl; /* * Voxelize the domain. */ // Voxelize the domain means: decide which lattice nodes are inside the obstacle and which are outside. pcout << std::endl << "Voxelizing the domain." << std::endl; plint extendedEnvelopeWidth = 2; // Extrapolated off-lattice BCs. const int flowType = voxelFlag::outside; VoxelizedDomain3D<T> voxelizedDomain ( boundary, flowType, param.boundingBox(), borderWidth, extendedEnvelopeWidth, blockSize ); pcout << getMultiBlockInfo(voxelizedDomain.getVoxelMatrix()) << std::endl; /* * Generate the lattice, the density and momentum blocks. */ pcout << "Generating the lattice, the rhoBar and j fields." << std::endl; MultiBlockLattice3D<T,DESCRIPTOR> *lattice = new MultiBlockLattice3D<T,DESCRIPTOR>(voxelizedDomain.getVoxelMatrix()); if (param.useSmago) { defineDynamics(*lattice, lattice->getBoundingBox(), new SmagorinskyBGKdynamics<T,DESCRIPTOR>(param.omega, param.cSmago)); pcout << "Using Smagorinsky BGK dynamics." << std::endl; } else { defineDynamics(*lattice, lattice->getBoundingBox(), new BGKdynamics<T,DESCRIPTOR>(param.omega)); pcout << "Using BGK dynamics." << std::endl; } bool velIsJ = false; defineDynamics(*lattice, voxelizedDomain.getVoxelMatrix(), lattice->getBoundingBox(), new NoDynamics<T,DESCRIPTOR>(), voxelFlag::inside); lattice->toggleInternalStatistics(false); MultiBlockManagement3D sparseBlockManagement(lattice->getMultiBlockManagement()); // The rhoBar and j fields are used at both the collision and at the implementation of the // outflow boundary condition. plint envelopeWidth = 1; MultiScalarField3D<T> *rhoBar = new MultiScalarField3D<T> ( MultiBlockManagement3D ( sparseBlockManagement.getSparseBlockStructure(), sparseBlockManagement.getThreadAttribution().clone(), envelopeWidth ), defaultMultiBlockPolicy3D().getBlockCommunicator(), defaultMultiBlockPolicy3D().getCombinedStatistics(), defaultMultiBlockPolicy3D().getMultiScalarAccess<T>() ); rhoBar->toggleInternalStatistics(false); MultiTensorField3D<T,3> *j = new MultiTensorField3D<T,3> ( MultiBlockManagement3D ( sparseBlockManagement.getSparseBlockStructure(), sparseBlockManagement.getThreadAttribution().clone(), envelopeWidth ), defaultMultiBlockPolicy3D().getBlockCommunicator(), defaultMultiBlockPolicy3D().getCombinedStatistics(), defaultMultiBlockPolicy3D().getMultiTensorAccess<T,3>() ); j->toggleInternalStatistics(false); std::vector<MultiBlock3D*> lattice_rho_bar_j_arg; lattice_rho_bar_j_arg.push_back(lattice); lattice_rho_bar_j_arg.push_back(rhoBar); lattice_rho_bar_j_arg.push_back(j); integrateProcessingFunctional( new ExternalRhoJcollideAndStream3D<T,DESCRIPTOR>(), lattice->getBoundingBox(), lattice_rho_bar_j_arg, 0); integrateProcessingFunctional( new BoxRhoBarJfunctional3D<T,DESCRIPTOR>(), lattice->getBoundingBox(), lattice_rho_bar_j_arg, 3); // rhoBar and j are computed at level 3 because // the boundary conditions are on levels 1 and 2. /* * Generate the off-lattice boundary condition on the obstacle and the outer-domain boundary conditions. */ pcout << "Generating boundary conditions." << std::endl; OffLatticeBoundaryCondition3D<T,DESCRIPTOR,Velocity> *boundaryCondition; BoundaryProfiles3D<T,Velocity> profiles; bool useAllDirections=true; OffLatticeModel3D<T,Velocity>* offLatticeModel=0; if (param.freeSlipWall) { profiles.setWallProfile(new FreeSlipProfile3D<T>); } else { profiles.setWallProfile(new NoSlipProfile3D<T>); } offLatticeModel = new GuoOffLatticeModel3D<T,DESCRIPTOR> ( new TriangleFlowShape3D<T,Array<T,3> >(voxelizedDomain.getBoundary(), profiles), flowType, useAllDirections ); offLatticeModel->setVelIsJ(velIsJ); boundaryCondition = new OffLatticeBoundaryCondition3D<T,DESCRIPTOR,Velocity>( offLatticeModel, voxelizedDomain, *lattice); boundaryCondition->insert(); // The boundary condition algorithm or the outer domain. OnLatticeBoundaryCondition3D<T,DESCRIPTOR>* outerBoundaryCondition = createLocalBoundaryCondition3D<T,DESCRIPTOR>(); outerDomainBoundaries(lattice, rhoBar, j, outerBoundaryCondition); /* * Implement the outlet sponge zone. */ if (param.numOutletSpongeCells > 0) { T bulkValue; Array<plint,6> numSpongeCells; if (param.outletSpongeZoneType == 0) { pcout << "Generating an outlet viscosity sponge zone." << std::endl; bulkValue = param.omega; } else if (param.outletSpongeZoneType == 1) { pcout << "Generating an outlet Smagorinsky sponge zone." << std::endl; bulkValue = param.cSmago; } else { pcout << "Error: unknown type of sponge zone." << std::endl; exit(-1); } // Number of sponge zone lattice nodes at all the outer domain boundaries. // So: 0 means the boundary at x = 0 // 1 means the boundary at x = nx-1 // 2 means the boundary at y = 0 // and so on... numSpongeCells[0] = 0; numSpongeCells[1] = param.numOutletSpongeCells; numSpongeCells[2] = 0; numSpongeCells[3] = 0; numSpongeCells[4] = 0; numSpongeCells[5] = 0; std::vector<MultiBlock3D*> args; args.push_back(lattice); if (param.outletSpongeZoneType == 0) { applyProcessingFunctional(new ViscositySpongeZone<T,DESCRIPTOR>( param.nx, param.ny, param.nz, bulkValue, numSpongeCells), lattice->getBoundingBox(), args); } else { applyProcessingFunctional(new SmagorinskySpongeZone<T,DESCRIPTOR>( param.nx, param.ny, param.nz, bulkValue, param.targetSpongeCSmago, numSpongeCells), lattice->getBoundingBox(), args); } } /* * Setting the initial conditions. */ // Initial condition: Constant pressure and velocity-at-infinity everywhere. Array<T,3> uBoundary(param.getInletVelocity(0), 0.0, 0.0); initializeAtEquilibrium(*lattice, lattice->getBoundingBox(), 1.0, uBoundary); applyProcessingFunctional( new BoxRhoBarJfunctional3D<T,DESCRIPTOR>(), lattice->getBoundingBox(), lattice_rho_bar_j_arg); // Compute rhoBar and j before VirtualOutlet is executed. lattice->executeInternalProcessors(1); // Execute all processors except the ones at level 0. lattice->executeInternalProcessors(2); lattice->executeInternalProcessors(3); /* * Particles (streamlines). */ // This part of the code that relates to particles, is purely for visualization // purposes. Particles are used to compute streamlines essentially. // Definition of a particle field. MultiParticleField3D<ParticleFieldT>* particles = 0; if (param.useParticles) { particles = new MultiParticleField3D<ParticleFieldT> ( lattice->getMultiBlockManagement(), defaultMultiBlockPolicy3D().getCombinedStatistics() ); std::vector<MultiBlock3D*> particleArg; particleArg.push_back(particles); std::vector<MultiBlock3D*> particleFluidArg; particleFluidArg.push_back(particles); particleFluidArg.push_back(lattice); // Functional that advances the particles to their new position at each predefined time step. integrateProcessingFunctional ( new AdvanceParticlesEveryWhereFunctional3D<T,DESCRIPTOR>(param.cutOffSpeedSqr), lattice->getBoundingBox(), particleArg, 0); // Functional that assigns the particle velocity according to the particle's position in the fluid. integrateProcessingFunctional ( new FluidToParticleCoupling3D<T,DESCRIPTOR>((T) param.particleTimeFactor), lattice->getBoundingBox(), particleFluidArg, 1 ); // Definition of a domain from which particles will be injected in the flow field. Box3D injectionDomain(0, 0, centerLB[1]-0.25*param.ny, centerLB[1]+0.25*param.ny, centerLB[2]-0.25*param.nz, centerLB[2]+0.25*param.nz); // Definition of simple mass-less particles. Particle3D<T,DESCRIPTOR>* particleTemplate=0; particleTemplate = new PointParticle3D<T,DESCRIPTOR>(0, Array<T,3>(0.,0.,0.), Array<T,3>(0.,0.,0.)); // Functional which injects particles with predefined probability from the specified injection domain. std::vector<MultiBlock3D*> particleInjectionArg; particleInjectionArg.push_back(particles); integrateProcessingFunctional ( new InjectRandomParticlesFunctional3D<T,DESCRIPTOR>(particleTemplate, param.particleProbabilityPerCell), injectionDomain, particleInjectionArg, 0 ); // Definition of an absorbtion domain for the particles. Box3D absorbtionDomain(param.outlet); // Functional which absorbs the particles which reach the specified absorbtion domain. integrateProcessingFunctional ( new AbsorbParticlesFunctional3D<T,DESCRIPTOR>, absorbtionDomain, particleArg, 0 ); particles->executeInternalProcessors(); } /* * Starting the simulation. */ plb_ofstream energyFile((outputDir+"average_energy.dat").c_str()); pcout << std::endl; pcout << "Starting simulation." << std::endl; for (plint i = 0; i < param.maxIter; ++i) { if (i <= param.initialIter) { Array<T,3> uBoundary(param.getInletVelocity(i), 0.0, 0.0); setBoundaryVelocity(*lattice, param.inlet, uBoundary); } if (i % param.statIter == 0) { pcout << "At iteration " << i << ", t = " << i*param.dt << std::endl; Array<T,3> force(boundaryCondition->getForceOnObject()); T factor = util::sqr(util::sqr(param.dx)) / util::sqr(param.dt); pcout << "Force on object over fluid density: F[x] = " << force[0]*factor << ", F[y] = " << force[1]*factor << ", F[z] = " << force[2]*factor << std::endl; T avEnergy = boundaryCondition->computeAverageEnergy() * util::sqr(param.dx) / util::sqr(param.dt); pcout << "Average kinetic energy over fluid density: E = " << avEnergy << std::endl; energyFile << i*param.dt << " " << avEnergy << std::endl; pcout << std::endl; } if (i % param.vtkIter == 0) { pcout << "Writing VTK at time t = " << i*param.dt << endl; writeVTK(*boundaryCondition, i); if (param.useParticles) { writeParticleVtk<T,DESCRIPTOR> ( *particles, createFileName(outputDir+"particles_", i, PADDING) + ".vtk", param.maxNumParticlesToWrite ); } } if (i % param.imageIter == 0) { pcout << "Writing PPM image at time t = " << i*param.dt << endl; writePPM(*boundaryCondition, i); } lattice->executeInternalProcessors(); lattice->incrementTime(); if (param.useParticles && i % param.particleTimeFactor == 0) { particles->executeInternalProcessors(); } } energyFile.close(); delete outerBoundaryCondition; delete boundaryCondition; if (param.useParticles) { delete particles; } delete j; delete rhoBar; delete lattice; }
// Instantiate the boundary conditions for the outer domain. void outerDomainBoundaries(MultiBlockLattice3D<T,DESCRIPTOR> *lattice, MultiScalarField3D<T> *rhoBar, MultiTensorField3D<T,3> *j, OnLatticeBoundaryCondition3D<T,DESCRIPTOR> *bc) { Array<T,3> uBoundary(param.getInletVelocity(0), 0.0, 0.0); if (param.lateralFreeSlip) { pcout << "Free-slip lateral boundaries." << std::endl; lattice->periodicity().toggleAll(false); rhoBar->periodicity().toggleAll(false); j->periodicity().toggleAll(false); bc->setVelocityConditionOnBlockBoundaries(*lattice, param.inlet, boundary::dirichlet); setBoundaryVelocity(*lattice, param.inlet, uBoundary); bc->setVelocityConditionOnBlockBoundaries(*lattice, param.lateral1, boundary::freeslip); bc->setVelocityConditionOnBlockBoundaries(*lattice, param.lateral2, boundary::freeslip); bc->setVelocityConditionOnBlockBoundaries(*lattice, param.lateral3, boundary::freeslip); bc->setVelocityConditionOnBlockBoundaries(*lattice, param.lateral4, boundary::freeslip); // The VirtualOutlet is a sophisticated outflow boundary condition. Box3D globalDomain(lattice->getBoundingBox()); std::vector<MultiBlock3D*> bcargs; bcargs.push_back(lattice); bcargs.push_back(rhoBar); bcargs.push_back(j); T outsideDensity = 1.0; int bcType = 1; integrateProcessingFunctional(new VirtualOutlet<T,DESCRIPTOR>(outsideDensity, globalDomain, bcType), param.outlet, bcargs, 2); } else { pcout << "Periodic lateral boundaries." << std::endl; lattice->periodicity().toggleAll(true); rhoBar->periodicity().toggleAll(true); j->periodicity().toggleAll(true); lattice->periodicity().toggle(0, false); rhoBar->periodicity().toggle(0, false); j->periodicity().toggle(0, false); bc->addVelocityBoundary0N(param.inlet, *lattice); setBoundaryVelocity(*lattice, param.inlet, uBoundary); // The VirtualOutlet is a sophisticated outflow boundary condition. // The "globalDomain" argument for the boundary condition must be // bigger than the actual bounding box of the simulation for // the directions which are periodic. Box3D globalDomain(lattice->getBoundingBox()); globalDomain.y0 -= 2; // y-periodicity globalDomain.y1 += 2; globalDomain.z0 -= 2; // z-periodicity globalDomain.z1 += 2; std::vector<MultiBlock3D*> bcargs; bcargs.push_back(lattice); bcargs.push_back(rhoBar); bcargs.push_back(j); T outsideDensity = 1.0; int bcType = 1; integrateProcessingFunctional(new VirtualOutlet<T,DESCRIPTOR>(outsideDensity, globalDomain, bcType), param.outlet, bcargs, 2); } }