Пример #1
0
    def initialize(self):
        # Need to modify this dictionary when we change the SA constants
        #import pdb; pdb.set_trace()
        #sys.stdout = open(os.devnull, "w")
        self.aoptions = aeroOptions
        self.woptions = warpOptions
        self.ooptions = optOptions
        self.uoptions = uqOptions

        self.Pr = 0.
        self.P = self.uoptions['P']
        self.NS0 = self.uoptions['NS0']
        # Generate FFD and DVs
        if rank == 0:
            rank0dvg = pf.createFFD()
        else:
            rank0dvg = None
        self.DVGeo = comm.bcast(rank0dvg, root=0)

        # starting flat mesh
        meshname = self.aoptions['gridFile']
        gridFile = meshname

        # flow characteristics
        alpha = 0.0
        mach = self.ooptions['mach']  #0.95
        Re = self.ooptions['Re']  #50000
        Re_L = 1.0
        temp = 540
        arearef = 2.0
        chordref = 1.0

        # Spalart Allmaras model constants, to be changed in UQ (4 for now)
        saconstsm = [0.41, 0.1355, 0.622, 0.66666666667]
        self.saconstsb = [7.1, 0.3, 2.0, 1.0, 2.0, 1.2, 0.5, 2.0]
        self.saconsts = saconstsm + self.saconstsb
        self.aoptions['SAConsts'] = self.saconsts
        #self.gridSol = f'{meshname}_{saconstsm}_sol'
        solname = self.ooptions['prob_name']
        self.gridSol = f'{solname}_sol'

        # Get a set of UQ sample points (LHS)
        #if self.ooptions['run_once']:
        #    self.sample = self.uoptions['dist']
        #else

        # Scatter samples, multi-point parallelism
        if self.uoptions['MCTimeBudget']:
            self.aps = []
            self.solvers = []
            self.meshes = []
            self.current_samples = self.NS0
            if rank == 0:
                rank0sam = plate_sa_lhs.genLHS(s=self.current_samples)
            else:
                rank0sam = None
            self.sample = comm.bcast(rank0sam, root=0)
            self.cases = divide_cases(self.NS0, size)
            # Scatter samples on each level, multi-point parallelism
            self.samplep = self.sample[self.cases[rank]]
            self.nsp = len(self.cases[rank])

            # Create solvers for the preliminary data
            for i in range(self.nsp):
                namestr = self.gridSol + "_" + str(self.cases[rank][i])

                # create meshes
                self.meshes.append(
                    USMesh(options=self.woptions, comm=MPI.COMM_SELF))

                # create aeroproblems
                self.aps.append(
                    AeroProblem(name=namestr,
                                alpha=alpha,
                                mach=mach,
                                reynolds=Re,
                                reynoldsLength=Re_L,
                                T=temp,
                                areaRef=arearef,
                                chordRef=chordref,
                                evalFuncs=['cd']))
                time.sleep(0.1)  # this solves a few problems for some reason
                # create solvers
                self.solvers.append(
                    ADFLOW(options=self.aoptions, comm=MPI.COMM_SELF))

                saconstsm = self.samplep[i].tolist()
                self.saconsts = saconstsm + self.saconstsb
                self.solvers[i].setOption('SAConsts', self.saconsts)
                self.solvers[i].setDVGeo(self.DVGeo)
                self.solvers[i].setMesh(self.meshes[i])
                print("what up %i", str(rank))
                coords = self.solvers[i].getSurfaceCoordinates(
                    groupName=self.solvers[i].allWallsGroup)
                self.solvers[i].DVGeo.addPointSet(coords, 'coords')

            # start looping over mesh levels
            sumt = 0.
            sumtp = 0.
            Et = 0.
            funcs = {}
            a_init = self.DVGeo.getValues()
            a_init['pnts'][:] = self.ooptions['DVInit']
            dvdict = {'pnts': a_init['pnts']}
            for i in range(self.nsp):
                saconstsm = self.samplep[i].tolist()
                self.saconsts = saconstsm + self.saconstsb
                self.solvers[i].setOption('SAConsts', self.saconsts)
                self.solvers[i].DVGeo.setDesignVars(dvdict)
                self.aps[i].setDesignVars(dvdict)
                pc0 = time.process_time()
                self.solvers[i](self.aps[i])
                self.solvers[i].evalFunctions(self.aps[i], funcs)
                pc1 = time.process_time()
                astr = self.gridSol + "_" + str(self.cases[rank][i]) + "_cd"
                sumtp += (pc1 - pc0)

            sumt = comm.allreduce(sumtp)
            Et = sumt / self.NS0
            self.NS = math.ceil(self.P / Et)
            self.Pr = self.NS * Et
        else:
            self.NS = self.uoptions['NS']

        #import pdb; pdb.set_trace()

        if rank == 0:
            rank0sam = plate_sa_lhs.genLHS(s=self.NS)
        else:
            rank0sam = None
        self.sample = comm.bcast(rank0sam, root=0)

        self.cases = divide_cases(self.NS, size)
        self.nsp = len(self.cases[rank])  #int(ns/size) # samples per processor
        #import pdb; pdb.set_trace()
        self.samplep = self.sample[self.cases[
            rank]]  #self.sample[(rank*self.nsp):(rank*self.nsp+(self.nsp))] #shouldn't really need to "scatter" per se
        #import pdb; pdb.set_trace()
        #assert len(self.samplep) == self.nsp

        # Actually create solvers (and aeroproblems?) (and mesh?) now
        self.aps = []
        self.solvers = []
        self.meshes = []

        #self.mesh = USMesh(options=self.woptions, comm=MPI.COMM_SELF)
        for i in range(self.nsp):
            namestr = self.gridSol + "_" + str(self.cases[rank][i])

            # create meshes
            self.meshes.append(
                USMesh(options=self.woptions, comm=MPI.COMM_SELF))

            # create aeroproblems
            self.aps.append(
                AeroProblem(name=namestr,
                            alpha=alpha,
                            mach=mach,
                            reynolds=Re,
                            reynoldsLength=Re_L,
                            T=temp,
                            areaRef=arearef,
                            chordRef=chordref,
                            evalFuncs=['cd']))
            time.sleep(0.1)  # this solves a few problems for some reason
            # create solvers
            self.solvers.append(
                ADFLOW(options=self.aoptions, comm=MPI.COMM_SELF))
            # if not self.ooptions['run_once']:
            # saconstsm = self.samplep[i].tolist()
            # else:
            saconstsm = self.samplep[i].tolist()
            self.saconsts = saconstsm + self.saconstsb
            self.solvers[i].setOption('SAConsts', self.saconsts)
            self.solvers[i].setDVGeo(self.DVGeo)
            self.solvers[i].setMesh(self.meshes[i])
            print("what up %i", str(rank))
            coords = self.solvers[i].getSurfaceCoordinates(
                groupName=self.solvers[i].allWallsGroup)
            self.solvers[i].DVGeo.addPointSet(coords, 'coords')

        # Set constraints, should only need one of those solvers, the meshes are all the same
        self.DVCon = DVConstraints()
        self.DVCon2 = DVConstraints()
        self.DVCon.setDVGeo(self.solvers[0].DVGeo.getFlattenedChildren()[1])
        self.DVCon2.setDVGeo(self.solvers[0].DVGeo)

        self.DVCon.setSurface(self.solvers[0].getTriangulatedMeshSurface(
            groupName='allSurfaces'))
        # set extra group for surface area condition
        self.DVCon2.setSurface(self.solvers[0].getTriangulatedMeshSurface(),
                               name='wall')

        # DV should be same into page (not doing anything right now)
        #import pdb; pdb.set_trace()
        lIndex = self.solvers[0].DVGeo.getFlattenedChildren()[1].getLocalIndex(
            0)
        indSetA = []
        indSetB = []
        nXc = optOptions['NX']
        self.NC = math.trunc(
            ((1.0 - self.ooptions['DVFraction']) * self.ooptions['NX']))
        ind = [
            int(nXc / 2) - int(self.NC / 2),
            int(nXc / 2) + int(self.NC / 2)
        ]
        for i in range(ind[0], ind[1]):
            indSetA.append(lIndex[i, 0, 1])
            indSetB.append(lIndex[i, 1, 1])
        # for i in range(lIndex.shape[0]):
        #     indSetA.append(lIndex[i, 0, 1])
        #     indSetB.append(lIndex[i, 1, 1])
        self.DVCon.addLinearConstraintsShape(indSetA,
                                             indSetB,
                                             factorA=1.0,
                                             factorB=-1.0,
                                             lower=0,
                                             upper=0,
                                             name='eqs')

        # Thickness constraints (one for each active DV)
        #import pdb; pdb.set_trace()

        # Maximum thickness of the domain, translates to minimum thickness of bump
        ub = 1.0 - self.ooptions['DCMinThick']
        tcf = self.ooptions['DCThickFrac']
        ra = self.ooptions['bumpBounds']
        lim = self.ooptions['DCMinArea']
        span = numpy.linspace(0, 1, nXc)
        xc = span * (ra[1] - ra[0]) + ra[0]
        #ind = range(int(nXc/2) - int(self.NC/2), int(nXc/2) + int(self.NC/2)))
        ind = [
            int(nXc / 2) - int(tcf * self.NC / 2),
            int(nXc / 2) + int(tcf * self.NC / 2)
        ]
        ptList = numpy.zeros([2, 3])
        ptList[:, 0] = xc[ind]
        ptList[:, 1] = 0.5
        ptList[:, 2] = 0.5

        if self.ooptions['use_area_con']:
            self.DVCon2.addSurfaceAreaConstraint(lower=lim,
                                                 upper=10.,
                                                 name='sas',
                                                 surfaceName='wall')
        else:
            self.DVCon2.addThicknessConstraints1D(ptList,
                                                  self.NC, [0, 0, 1],
                                                  lower=0.5,
                                                  upper=ub,
                                                  name='tcs')

        print("excuse me")
        dummy = rank
        dsum = comm.allgather(dummy)

        sys.stdout = sys.__stdout__
Пример #2
0
import plate_ffd as pf
import math
from mpi4py import MPI
from idwarp import USMesh
from baseclasses import *
from adflow import ADFLOW
from pygeo import DVGeometry, DVConstraints
from plate_comp_opts import aeroOptions, warpOptions, optOptions
'''Just generate a mesh moved with a set of design variables'''

aoptions = aeroOptions
woptions = warpOptions
ooptions = optOptions

# Generate FFD and DVs
DVGeo = pf.createFFD()

# starting flat mesh
meshname = aoptions['gridFile']

mesh = USMesh(options=warpOptions)
coords = mesh.getSurfaceCoordinates()

DVGeo.addPointSet(coords, "coords")

vars = optOptions['ro_shape']
dvDict = {'pnts': vars}
DVGeo.setDesignVars(dvDict)
new_coords = DVGeo.update("coords")

# move the mesh using idwarp
Пример #3
0
    def initialize(self):
        # Need to modify this dictionary when we change the SA constants
        #import pdb; pdb.set_trace()
        #sys.stdout = open(os.devnull, "w")
        self.aoptions = aeroOptions
        self.woptions = warpOptions
        self.ooptions = optOptions
        self.uoptions = uqOptions

        self.Pr = 0.
        # Generate FFD and DVs
        if rank == 0:
            rank0dvg = pf.createFFD()
        else:
            rank0dvg = None
        self.DVGeo = comm.bcast(rank0dvg, root=0)

        # Get a full list of every mesh name we have, assume they are ordered properly by level
        self.meshnames = self.uoptions['gridFileLevels']
        self.Lmax = len(self.meshnames)  #as many levels as we have meshes
        self.mord = [*range(self.Lmax)]
        self.mord.reverse()

        if self.Lmax < 3:
            raise ValueError('Not enough meshes available, ' + self.Lmax +
                             ' < 3')

        # Spalart Allmaras model constants, to be changed in UQ (4 for now)
        saconstsm = [0.41, 0.1355, 0.622, 0.66666666667]
        self.saconstsb = [7.1, 0.3, 2.0, 1.0, 2.0, 1.2, 0.5, 2.0]
        self.saconsts = saconstsm + self.saconstsb
        self.aoptions['SAConsts'] = self.saconsts
        #self.gridSol = f'{meshname}_{saconstsm}_sol'
        solname = self.ooptions['prob_name']
        self.gridSol = f'{solname}_sol'

        self.cases = []
        #self.nsp = []   #keep track per level
        self.samplep = []
        self.naddedtot = []
        for i in range(self.Lmax):
            self.naddedtot.append(0)

        self.aps = []
        self.solvers = []
        self.meshes = []

        self.NS0 = self.uoptions['NS0']
        self.current_samples = self.NS0 * self.Lmax
        self.N1 = None
        self.a1 = None
        self.P = self.uoptions['P']
        ##########
        # call distribute samples here?
        if not self.uoptions['use-predetermined-samples']:
            self.MFMC()
        else:
            self.N1 = self.uoptions['predet-N1']
            self.a1 = self.uoptions['predet-a1']

        self.dist_samples()

        ##########

        # Set constraints, should only need one of those solvers, the meshes are all the same
        if rank == 0:
            self.DVCon = DVConstraints()
            self.DVCon2 = DVConstraints()
            self.DVCon.setDVGeo(
                self.solvers[0][0].DVGeo.getFlattenedChildren()[1])
            self.DVCon2.setDVGeo(self.solvers[0][0].DVGeo)

            self.DVCon.setSurface(
                self.solvers[0][0].getTriangulatedMeshSurface(
                    groupName='allSurfaces'))
            # set extra group for surface area condition
            self.DVCon2.setSurface(
                self.solvers[0][0].getTriangulatedMeshSurface(), name='wall')

            # DV should be same into page (not doing anything right now)
            #import pdb; pdb.set_trace()
            lIndex = self.solvers[0][0].DVGeo.getFlattenedChildren(
            )[1].getLocalIndex(0)
            indSetA = []
            indSetB = []
            nXc = optOptions['NX']
            self.NC = math.trunc(
                ((1.0 - self.ooptions['DVFraction']) * self.ooptions['NX']))
            ind = [
                int(nXc / 2) - int(self.NC / 2),
                int(nXc / 2) + int(self.NC / 2)
            ]
            for i in range(ind[0], ind[1]):
                indSetA.append(lIndex[i, 0, 1])
                indSetB.append(lIndex[i, 1, 1])
            # for i in range(lIndex.shape[0]):
            #     indSetA.append(lIndex[i, 0, 1])
            #     indSetB.append(lIndex[i, 1, 1])
            self.DVCon.addLinearConstraintsShape(indSetA,
                                                 indSetB,
                                                 factorA=1.0,
                                                 factorB=-1.0,
                                                 lower=0,
                                                 upper=0,
                                                 name='eqs')

            # Thickness constraints (one for each active DV)
            #import pdb; pdb.set_trace()

            # Maximum thickness of the domain, translates to minimum thickness of bump
            ub = 1.0 - self.ooptions['DCMinThick']
            tcf = self.ooptions['DCThickFrac']
            ra = self.ooptions['bumpBounds']
            lim = self.ooptions['DCMinArea']
            span = numpy.linspace(0, 1, nXc)
            xc = span * (ra[1] - ra[0]) + ra[0]
            #ind = range(int(nXc/2) - int(self.NC/2), int(nXc/2) + int(self.NC/2)))
            ind = [
                int(nXc / 2) - int(tcf * self.NC / 2),
                int(nXc / 2) + int(tcf * self.NC / 2)
            ]
            ptList = numpy.zeros([2, 3])
            ptList[:, 0] = xc[ind]
            ptList[:, 1] = 0.5
            ptList[:, 2] = 0.5

            if self.ooptions['use_area_con']:
                self.DVCon2.addSurfaceAreaConstraint(lower=lim,
                                                     upper=10.,
                                                     name='sas',
                                                     surfaceName='wall')
            else:
                self.DVCon2.addThicknessConstraints1D(ptList,
                                                      self.NC, [0, 0, 1],
                                                      lower=0.5,
                                                      upper=ub,
                                                      name='tcs')

        dummy = rank
        dsum = comm.allgather(dummy)

        sys.stdout = sys.__stdout__
Пример #4
0
    def initialize(self):
        # Need to modify this dictionary when we change the SA constants
        sys.stdout = open(os.devnull, "w")
        self.aoptions = aeroOptions
        self.woptions = warpOptions
        self.ooptions = optOptions

        # Generate FFD and DVs
        self.DVGeo = pf.createFFD()

        # starting flat mesh
        meshname = self.aoptions['gridFile']
        gridFile = meshname
        
        # flow characteristics
        alpha = 0.0
        mach = self.ooptions['mach']#0.95
        Re = self.ooptions['Re']#50000
        Re_L = 1.0
        temp = 540
        arearef = 2.0
        chordref = 1.0

        # Spalart Allmaras model constants, to be changed in UQ
        saconstsm = [0.41, 0.1355, 0.622, 0.66666666667, 7.1, 0.3, 2.0]
        self.saconsts = saconstsm + [1.0, 2.0, 1.2, 0.5, 2.0]
        self.aoptions['SAConsts'] = self.saconsts
        #self.gridSol = f'{meshname}_{saconstsm}_sol'
        solname = self.ooptions['prob_name']
        self.gridSol = f'{solname}_sol'

        # Aerodynamic problem description
        self.ap = AeroProblem(name=self.gridSol, alpha=alpha, mach=mach, reynolds=Re, reynoldsLength=Re_L, T=temp, areaRef=arearef, chordRef=chordref, 
        evalFuncs=['cd'])

        # Create solver
        self.CFDSolver = ADFLOW(options=self.aoptions, comm=MPI.COMM_WORLD)
        self.CFDSolver.setDVGeo(self.DVGeo)

        # Set up mesh warping
        self.mesh = USMesh(options=self.woptions, comm=MPI.COMM_WORLD)
        self.CFDSolver.setMesh(self.mesh)

        # Try setting the DVGeo coordinates here
        coords = self.CFDSolver.getSurfaceCoordinates(groupName=self.CFDSolver.allWallsGroup)
        self.CFDSolver.DVGeo.addPointSet(coords, 'coords')
        self.CFDSolver.DVGeo.getFlattenedChildren()[1].writePlot3d("ffdp_opt_def.xyz")


        # Set constraints
        self.DVCon = DVConstraints()
        self.DVCon2 = DVConstraints()
        self.DVCon.setDVGeo(self.CFDSolver.DVGeo.getFlattenedChildren()[1])
        self.DVCon2.setDVGeo(self.CFDSolver.DVGeo)

        self.DVCon.setSurface(self.CFDSolver.getTriangulatedMeshSurface(groupName='allSurfaces'))
        # set extra group for surface area condition
        self.DVCon2.setSurface(self.CFDSolver.getTriangulatedMeshSurface(), name='wall')

        # DV should be same into page (not doing anything right now)
        #import pdb; pdb.set_trace()
        lIndex = self.CFDSolver.DVGeo.getFlattenedChildren()[1].getLocalIndex(0)
        indSetA = []
        indSetB = []
        nXc = optOptions['NX']
        self.NC = math.trunc(((1.0 - self.ooptions['DVFraction'])*self.ooptions['NX']))
        ind = [int(nXc/2) - int(self.NC/2), int(nXc/2) + int(self.NC/2)]
        for i in range(ind[0], ind[1]):
            indSetA.append(lIndex[i, 0, 1])
            indSetB.append(lIndex[i, 1, 1])
        # for i in range(lIndex.shape[0]):
        #     indSetA.append(lIndex[i, 0, 1])
        #     indSetB.append(lIndex[i, 1, 1])
        self.DVCon.addLinearConstraintsShape(indSetA, indSetB, factorA=1.0, factorB=-1.0, lower=0, upper=0, name='eqs')

        # Thickness constraints (one for each active DV)
        #import pdb; pdb.set_trace()

        # Maximum thickness of the domain, translates to minimum thickness of bump
        ub = 1.0 - self.ooptions['DCMinThick']
        tcf = self.ooptions['DCThickFrac']
        ra = self.ooptions['bumpBounds']
        lim = self.ooptions['DCMinArea']
        span = numpy.linspace(0, 1, nXc)
        xc = span * (ra[1] - ra[0]) + ra[0]
        #ind = range(int(nXc/2) - int(self.NC/2), int(nXc/2) + int(self.NC/2)))
        ind = [int(nXc/2) - int(tcf*self.NC/2), int(nXc/2) + int(tcf*self.NC/2)]
        ptList = numpy.zeros([2, 3])
        ptList[:,0] = xc[ind]
        ptList[:,1] = 0.5
        ptList[:,2] = 0.5

        if self.ooptions['use_area_con']:
            self.DVCon2.addSurfaceAreaConstraint(lower=lim, upper=10., name='sas', surfaceName='wall')
        else:
            self.DVCon2.addThicknessConstraints1D(ptList, self.NC, [0,0,1], lower=0.5, upper=ub, name='tcs')

        sys.stdout = sys.__stdout__