def setUp(self): gridFile = os.path.join(baseDir, '../input_files/pipe.cgns') self.options = {'gridfile': gridFile, 'mgcycle':'sg', 'ncycles':1000, 'useanksolver':True, 'usenksolver':True, 'volumevariables': ['temp', 'mach', 'resrho' ], 'surfacevariables':['temp', 'vx', 'vy', 'vz', 'p', 'ptloss', 'mach', 'rho'], 'equationType':'euler', 'l2convergence': 1e-13} CFDSolver = ADFLOW(options=self.options) CFDSolver.addFunction('mdot', 'inlet', name="mdot_in") CFDSolver.addFunction('mdot', 'outlet', name="mdot_out") CFDSolver.addFunction('mavgptot', 'outlet', name="mavgptot_out") CFDSolver.addFunction('mavgptot', 'inlet', name="mavgptot_in") CFDSolver.addFunction('aavgptot', 'outlet', name="aavgptot_out") CFDSolver.addFunction('aavgptot', 'inlet', name="aavgptot_in") CFDSolver.addFunction('mavgttot', 'outlet', name="mavgttot_out") CFDSolver.addFunction('mavgttot', 'inlet', name="mavgttot_in") CFDSolver.addFunction('mavgps', 'outlet', name="mavgps_out") CFDSolver.addFunction('mavgps', 'inlet', name="mavgps_in") CFDSolver.addFunction('aavgps', 'outlet', name="aavgps_out") CFDSolver.addFunction('aavgps', 'inlet', name="aavgps_in") CFDSolver.addFunction('area', 'inlet', name="area_in") CFDSolver.addFunction('area', 'outlet', name="area_out") CFDSolver.addFunction('mavgvx', 'inlet', name="vx_in") CFDSolver.addFunction('mavgvx', 'outlet', name="vx_out") CFDSolver.addFunction('mavgps', 'inlet', name="ps_in") CFDSolver.addFunction('mavgps', 'outlet', name="ps_out") self.CFDSolver = CFDSolver self.ap = AeroProblem(name='actuator_in_pipe', alpha=00, mach=0.6, altitude=0, areaRef=1.0, chordRef=1.0, evalFuncs=['mdot_in', 'mdot_out', 'mavgptot_in', 'mavgptot_out', 'mavgttot_in', 'mavgttot_out', 'mavgps_in', 'mavgps_out', 'area_in', 'area_out', 'aavgps_in', 'aavgps_out', 'aavgptot_in', 'aavgptot_out', 'ps_in', 'ps_out', 'vx_in', 'vx_out'] ) self.force = 600 actuatorFile = os.path.join(baseDir, '../input_files/actuator_disk.xyz') self.CFDSolver.addActuatorRegion(actuatorFile, np.array([0,0,0]),np.array([1,0,0]), 'actuator', thrust=self.force )
def regression_test(self, handler): ''' This is where the actual testing happens. ''' gridFile = 'input_files/euler_conv_nozzle.cgns' options = copy.copy(adflowDefOpts) options.update({ 'gridfile': gridFile, 'equationType': 'euler', 'smoother': 'dadi', 'liftIndex': 2, 'CFL': 3., 'CFLCoarse': 1.5, 'MGCycle': 'sg', 'MGStartLevel': 1, 'nCyclesCoarse': 500, 'nCycles': 2500, 'monitorvariables': ['resrho', 'cl', 'cd', 'yplus'], 'nsubiterturb': 3, 'useNKSolver': True, 'NKSubSpaceSize': 60, 'L2Convergence': 1e-14, 'L2ConvergenceCoarse': 1e-2, 'NKSwitchTol': 1e-2, 'nkadpc': False, 'vis4': 0.006, 'vis2': 0.0, 'blocksplitting': True, 'solutionPrecision': 'double', 'flowtype': 'internal', 'useblockettes': False }) # Setup aeroproblem ap = AeroProblem( name='conv_nozzle', alpha=00.0, mach=0.25, T=500, P=79326.7, areaRef=1., chordRef=2., R=287.87, evalFuncs=[ 'mdot', 'mdot_up', 'mdot_down', 'mavgptot_up', 'mavgptot_down', 'aavgptot_up', 'aavgptot_down', 'mavgttot_up', 'mavgttot_down', 'mavgps_up', 'mavgps_down', 'aavgps_up', 'aavgps_down', 'mavgmn_up', 'mavgmn_down', 'thrust', 'thrust_pressure', 'thrust_viscous', 'thrust_momentum' ]) # Create the solver CFDSolver = ADFLOW(options=options) CFDSolver.addFamilyGroup('upstream', ['INFLOW']) CFDSolver.addFamilyGroup('downstream', ['OUTFLOW']) CFDSolver.addFamilyGroup('all_flow', ['INFLOW', 'OUTFLOW']) CFDSolver.addFunction('mdot', 'upstream', name="mdot_up") CFDSolver.addFunction('mdot', 'downstream', name="mdot_down") CFDSolver.addFunction('mavgptot', 'downstream', name="mavgptot_down") CFDSolver.addFunction('mavgptot', 'upstream', name="mavgptot_up") CFDSolver.addFunction('aavgptot', 'downstream', name="aavgptot_down") CFDSolver.addFunction('aavgptot', 'upstream', name="aavgptot_up") CFDSolver.addFunction('mavgttot', 'downstream', name="mavgttot_down") CFDSolver.addFunction('mavgttot', 'upstream', name="mavgttot_up") CFDSolver.addFunction('mavgps', 'downstream', name="mavgps_down") CFDSolver.addFunction('mavgps', 'upstream', name="mavgps_up") CFDSolver.addFunction('aavgps', 'downstream', name="aavgps_down") CFDSolver.addFunction('aavgps', 'upstream', name="aavgps_up") CFDSolver.addFunction('mavgmn', 'downstream', name="mavgmn_down") CFDSolver.addFunction('mavgmn', 'upstream', name="mavgmn_up") CFDSolver.addFunction( 'drag', 'all_flow', name="thrust") # this naming makes it seem like wishful thinking CFDSolver.addFunction('dragpressure', 'all_flow', name="thrust_pressure") CFDSolver.addFunction('dragviscous', 'all_flow', name="thrust_viscous") CFDSolver.addFunction('dragmomentum', 'all_flow', name="thrust_momentum") # Run test # CFDSolver.getResidual(ap) CFDSolver(ap) # Check the residual res = CFDSolver.getResidual(ap) totalR0, totalRStart, totalRFinal = CFDSolver.getResNorms() res /= totalR0 handler.par_add_norm(res, 1e-10, 1e-10) # Get and check the states handler.par_add_norm(CFDSolver.getStates(), 1e-10, 1e-10) funcs = {} CFDSolver.evalFunctions(ap, funcs) handler.root_add_dict(funcs, 1e-10, 1e-10)
def regression_test(self, handler, solve=False): ''' This is where the actual testing happens. ''' # gridFile = 'input_files/conic_conv_nozzle.cgns' gridFile = '../python/inputFiles/conic_conv_nozzle.cgns' options = copy.copy(adflowDefOpts) options.update({ # Common Parameters 'gridfile': gridFile, # Physics Parameters 'equationType': 'euler', 'smoother': 'dadi', 'nsubiter': 3, 'CFL': 4.0, 'CFLCoarse': 1.25, 'MGCycle': 'sg', 'MGStartLevel': -1, 'nCyclesCoarse': 250, 'nCycles': 1000, 'nkcfl0': 1e10, 'monitorvariables': ['cpu', 'resrho', 'cl', 'cd'], 'volumevariables': ['blank'], 'surfacevariables': ['mach', 'cp', 'vx', 'vy', 'vz', 'blank'], 'useNKSolver': True, 'nkswitchtol': .01, 'nkadpc': True, 'nkjacobianlag': 5, 'nkouterpreconits': 3, 'nkinnerpreconits': 2, # Convergence Parameters 'L2Convergence': 1e-10, 'L2ConvergenceCoarse': 1e-4, 'adjointl2convergence': 1e-6, 'forcesAsTractions': True, 'debugzipper': True, 'nearwalldist': .001, 'nkls': 'none', 'solutionprecision': 'double', 'adjointsubspacesize': 200, 'outerpreconits': 3, 'zipperSurfaceFamily': 'output_fam', 'flowtype': 'internal', }) if not solve: options['restartfile'] = gridFile # Setup aeroproblem ap = AeroProblem( name='nozzle', alpha=90.0, mach=0.5, altitude=0, areaRef=1.0, chordRef=1.0, R=287.87, evalFuncs=[ 'mdot_up', 'mdot_down', #'mdot_plane', 'mavgptot_up', 'mavgptot_down', # 'mavgptot_plane', 'aavgptot_up', 'aavgptot_down', # 'aavgptot_plane', 'mavgttot_up', 'mavgttot_down', # 'mavgttot_plane', 'mavgps_up', 'mavgps_down', #'mavgps_plane' 'aavgps_up', 'aavgps_down', #'aavgps_plane' ]) ap.setBCVar('Pressure', 79326.7, 'downstream') ap.addDV('Pressure', family='downstream') ap.setBCVar('PressureStagnation', 100000.0, 'upstream') ap.addDV('PressureStagnation', family='upstream') ap.setBCVar('TemperatureStagnation', 500.0, 'upstream') ap.addDV('TemperatureStagnation', family='upstream') # Create the solver CFDSolver = ADFLOW(options=options) CFDSolver.addFamilyGroup('upstream', ['inlet']) CFDSolver.addFamilyGroup('downstream', ['outlet']) CFDSolver.addFamilyGroup('all_flow', ['inlet', 'outlet']) CFDSolver.addFamilyGroup('output_fam', ['all_flow', 'allWalls']) CFDSolver.addFunction('mdot', 'upstream', name="mdot_up") CFDSolver.addFunction('mdot', 'downstream', name="mdot_down") CFDSolver.addFunction('mavgptot', 'downstream', name="mavgptot_down") CFDSolver.addFunction('mavgptot', 'upstream', name="mavgptot_up") CFDSolver.addFunction('aavgptot', 'downstream', name="aavgptot_down") CFDSolver.addFunction('aavgptot', 'upstream', name="aavgptot_up") CFDSolver.addFunction('mavgttot', 'downstream', name="mavgttot_down") CFDSolver.addFunction('mavgttot', 'upstream', name="mavgttot_up") CFDSolver.addFunction('mavgps', 'downstream', name="mavgps_down") CFDSolver.addFunction('mavgps', 'upstream', name="mavgps_up") CFDSolver.addFunction('aavgps', 'downstream', name="aavgps_down") CFDSolver.addFunction('aavgps', 'upstream', name="aavgps_up") CFDSolver.setOption('ncycles', 1000) # Run test # CFDSolver(ap) # Check the residual res = CFDSolver.getResidual(ap) handler.par_add_norm(res, 1e-10, 1e-10, msg='res') # Get and check the states handler.par_add_norm(CFDSolver.getStates(), 1e-10, 1e-10, msg='states') funcs = {} CFDSolver.evalFunctions(ap, funcs) handler.root_add_dict(funcs, 1e-10, 1e-10, msg='functions')
def setUp(self): # import petsc4py # petsc4py.init(arch='real-debug-gfortran-3.7.7') # from petsc4py import PETSc gridFile = os.path.join(baseDir, '../input_files/conic_conv_nozzle_mb_L4_array.cgns') intSurfFile = os.path.join(baseDir, '../input_files/integration_plane_viscous.fmt') self.options = {'gridfile': gridFile} self.options['mgstartlevel'] = 1 self.options['mgstartlevel'] = 1 self.options['mgcycle'] = 'sg' self.options['ncycles'] = 1 self.options['useanksolver'] = False self.options['l2convergence'] = 1e-12 ap = AeroProblem(name='nozzle_flow', alpha=90, mach=0.5, altitude=0, areaRef=1.0, chordRef=1.0, R=287.87, evalFuncs=['mdot_up', 'mdot_down', 'mdot_plane', 'mavgptot_up', 'mavgptot_down', 'mavgptot_plane', 'mavgttot_up', 'mavgttot_down', 'mavgttot_plane', 'mavgps_up', 'mavgps_down', 'mavgps_plane', ]) self.ap = ap CFDSolver = ADFLOW(options=self.options) CFDSolver.addIntegrationSurface(intSurfFile, 'viscous_plane') CFDSolver.finalizeUserIntegrationSurfaces() CFDSolver.addFamilyGroup('upstream',['inlet']) CFDSolver.addFamilyGroup('downstream',['outlet']) CFDSolver.addFamilyGroup('all_flow',['inlet', 'outlet']) CFDSolver.addFamilyGroup('output_fam',['all_flow', 'allWalls']) CFDSolver.addFunction('mdot', 'upstream', name="mdot_up") CFDSolver.addFunction('mdot', 'downstream', name="mdot_down") CFDSolver.addFunction('mdot', 'viscous_plane', name="mdot_plane") CFDSolver.addFunction('mavgptot', 'downstream', name="mavgptot_down") CFDSolver.addFunction('mavgptot', 'upstream', name="mavgptot_up") CFDSolver.addFunction('mavgptot', 'viscous_plane', name="mavgptot_plane") CFDSolver.addFunction('aavgptot', 'downstream', name="aavgptot_down") CFDSolver.addFunction('aavgptot', 'upstream', name="aavgptot_up") CFDSolver.addFunction('aavgptot', 'viscous_plane', name="aavgptot_plane") CFDSolver.addFunction('mavgttot', 'downstream', name="mavgttot_down") CFDSolver.addFunction('mavgttot', 'upstream', name="mavgttot_up") CFDSolver.addFunction('mavgttot', 'viscous_plane', name="mavgttot_plane") CFDSolver.addFunction('mavgps', 'downstream', name="mavgps_down") CFDSolver.addFunction('mavgps', 'upstream', name="mavgps_up") CFDSolver.addFunction('mavgps', 'viscous_plane', name="mavgps_plane") CFDSolver.addFunction('aavgps', 'downstream', name="aavgps_down") CFDSolver.addFunction('aavgps', 'upstream', name="aavgps_up") CFDSolver.addFunction('aavgps', 'viscous_plane', name="aavgps_plane") self.CFDSolver= CFDSolver self.comm = MPI.COMM_WORLD