Пример #1
0
def newtonSolver_MG(unsteadyResidual,MF_Jacobian,main,linear_solver,sparse_quadrature,eqns):
  n_levels = int(np.log(np.amin(main.order))/np.log(2)) 
  coarsen = np.int32(2**np.linspace(0,n_levels-1,n_levels))
  mg_classes = []
  mg_Rn = []
  mg_an = []
  #eqns2 = equations('Navier-Stokes',('roe','Inviscid'),'DNS')
  mg_b = []
  mg_e = []
  for i in range(0,n_levels):
    mg_classes.append( variables(main.Nel,main.order/coarsen[i],main.quadpoints/(2*coarsen[i]),eqns,main.mus,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,'DNS',main.procx,main.procy,main.BCs,main.source,main.source_mag,main.shock_capturing) )
    mg_classes[i].basis = main.basis
    mg_Rn.append( np.zeros(np.shape(mg_classes[i].RHS)) )
    mg_an.append( np.zeros(np.shape(mg_classes[i].a.a) ) )
    mg_b.append( np.zeros(np.size(mg_classes[i].RHS)) )
    mg_e.append(  np.zeros(np.size(mg_classes[i].RHS)) )
  def newtonHook(main,mg_classes,mg_Rn,mg_an):
    for i in range(0,n_levels):
      mg_classes[i].a.a[:] = main.a.a[:,0:main.order[0]/coarsen[i],0:main.order[1]/coarsen[i],0:main.order[2]/coarsen[i]]
      mg_classes[i].getRHS(mg_classes[i],mg_classes[i],eqns)
      mg_Rn[i][:] = mg_classes[i].RHS[:]
      mg_an[i][:] = mg_classes[i].a.a[:]
      mg_e[i][:] = 0. 

  def mv_resid(MF_Jacobian,args,main,v,b):
    return b - MF_Jacobian(v,args,main)

  Rstarn,Rn,Rstar_glob = unsteadyResidual(main.a.a)

  NLiter = 0
  an = np.zeros(np.shape(main.a0))
  an[:] = main.a0[:]
  Rstar_glob0 = Rstar_glob*1.
  old = np.zeros(np.shape(main.a.a))

  while (Rstar_glob >= 1e-20 and Rstar_glob/Rstar_glob0 > 1e-8):
    NLiter += 1
    ts = time.time()
    old[:] = 0.
    newtonHook(main,mg_classes,mg_Rn,mg_an)
    mg_b[0][:] = -Rstarn.flatten()
    for i in range(0,1):
      for j in range(0,n_levels):
        MF_Jacobian_args = [mg_an[j],mg_Rn[j]]
        mg_e[j][:] = linear_solver.solve(MF_Jacobian,mg_b[j].flatten(),np.zeros(np.size(mg_b[j])),mg_classes[j],MF_Jacobian_args,tol=1e-5,maxiter_outer=1,maxiter=10,printnorm=0)
        Resid  =  np.reshape( mv_resid(MF_Jacobian,MF_Jacobian_args,mg_classes[j],mg_e[j],mg_b[j].flatten()) , np.shape(mg_classes[j].a.a ) )
        if (j != n_levels-1):
          mg_b[j+1]= Resid[:,0:main.order[0]/coarsen[j+1],0:main.order[1]/coarsen[j+1],0:main.order[2]/coarsen[j+1]]
      for j in range(n_levels-2,-1,-1):
        etmp = np.reshape(mg_e[j][:],np.shape(mg_classes[j].a.a))
        etmp[:,0:main.order[0]/coarsen[j+1],0:main.order[1]/coarsen[j+1],0:main.order[2]/coarsen[j+1]] += np.reshape(mg_e[j+1],np.shape(mg_classes[j+1].a.a))
        MF_Jacobian_args = [mg_an[j],mg_Rn[j]]
        mg_e[j][:] = linear_solver.solve(MF_Jacobian,mg_b[j].flatten(),etmp.flatten(),mg_classes[j],MF_Jacobian_args,tol=1e-6,maxiter_outer=1,maxiter=10,printnorm=0)

    main.a.a[:] = an[:] + np.reshape(mg_e[0],np.shape(main.a.a))
    an[:] = main.a.a[:]
    Rstarn,Rn,Rstar_glob = unsteadyResidual(main.a.a)
    if (main.mpi_rank == 0):
      sys.stdout.write('NL iteration = ' + str(NLiter) + '  NL residual = ' + str(Rstar_glob) + ' relative decrease = ' + str(Rstar_glob/Rstar_glob0) + ' Solve time = ' + str(time.time() - ts)  + '\n')
      sys.stdout.flush()
Пример #2
0
def newtonSolver(unsteadyResidual,MF_Jacobian,main,linear_solver,sparse_quadrature,eqns):
  if (sparse_quadrature):
    coarsen = 2
    main_coarse = variables(main.Nel,main.order,main.quadpoints/(coarsen),eqns,main.mus,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,'DNS',main.procx,main.procy,main.BCs,main.source,main.source_mag)
    main_coarse.a.a[:] = main.a.a[:]
    def newtonHook(main_coarse,main,Rn):
      main_coarse.a.a[:] = main.a.a[:]
      main_coarse.getRHS(main_coarse,main_coarse,eqns)
      Rn[:] = main_coarse.RHS[:]
  else: 
    main_coarse = main
    def newtonHook(main_coarse,main,Rn):
       pass
  Rstarn,Rn,Rstar_glob = unsteadyResidual(main.a.a)
  NLiter = 0
  an = np.zeros(np.shape(main.a0))
  an[:] = main.a0[:]
  Rstar_glob0 = Rstar_glob*1.
  while (Rstar_glob >= 1e-10 and Rstar_glob/Rstar_glob0 > 1e-9):
    NLiter += 1
    ts = time.time()
    newtonHook(main_coarse,main,Rn)
    MF_Jacobian_args = [an,Rn]
    sol = linear_solver.solve(MF_Jacobian, -Rstarn.flatten(), np.zeros(np.size(main.a.a)),main_coarse,MF_Jacobian_args, linear_solver.tol,linear_solver.maxiter_outer,linear_solver.maxiter,linear_solver.printnorm)
    main.a.a[:] = an[:] + np.reshape(sol,np.shape(main.a.a))
    an[:] = main.a.a[:]
    Rstarn,Rn,Rstar_glob = unsteadyResidual(main.a.a)
    if (main.mpi_rank == 0):
      sys.stdout.write('NL iteration = ' + str(NLiter) + '  NL residual = ' + str(Rstar_glob) + ' relative decrease = ' + str(Rstar_glob/Rstar_glob0) + ' Solve time = ' + str(time.time() - ts)  + '\n')
      sys.stdout.flush()
Пример #3
0
def advanceSolImplicit_MG(main, MZ, eqns):
    main.a0[:] = main.a.a[:]
    main.getRHS(main, eqns)
    R0 = np.zeros(np.shape(main.RHS))
    R0[:] = main.RHS[:]

    def unsteadyResid(v):
        main.a.a[:] = np.reshape(v, np.shape(main.a.a))
        main.getRHS(main, eqns)
        R1 = np.zeros(np.shape(main.RHS))
        R1[:] = main.RHS[:]
        #Rstar = np.reshape( (v.flatten() - main.a0.flatten() ) - 0.5*main.dt*(R0 + R1).flatten() , np.shape(main.a.a))
        Rstar = (main.a.a[:] - main.a0) - 0.5 * main.dt * (R0 + R1)
        ## Create Global residual
        data = main.comm.gather(np.linalg.norm(Rstar)**2, root=0)
        if (main.mpi_rank == 0):
            Rstar_glob = 0.
            for j in range(0, main.num_processes):
                Rstar_glob += data[j]
            Rstar_glob = np.sqrt(Rstar_glob)
            for j in range(1, main.num_processes):
                main.comm.send(Rstar_glob, dest=j)
        else:
            Rstar_glob = main.comm.recv(source=0)
        return Rstar, R1, Rstar_glob

    Rstarn, Rn, Rstar_glob = unsteadyResid(main.a.a)
    NLiter = 0
    Rstar_glob0 = Rstar_glob * 1.
    if (main.mpi_rank == 0):
        print(
            'NL iteration = ' + str(NLiter) + '  NL residual = ' +
            str(Rstar_glob),
            ' relative decrease = ' + str(Rstar_glob / Rstar_glob0))

    coarsen = 2
    coarsen2 = 4
    old = np.zeros(np.shape(main.a.a))
    Rstar_glob0 = Rstar_glob * 1.
    main_coarse = variables(main.Nel, main.order / coarsen,
                            main.quadpoints / (2 * coarsen), eqns, main.mu,
                            main.xG, main.yG, main.zG, main.t, main.et,
                            main.dt, main.iteration, main.save_freq, 'DNS',
                            main.procx, main.procy)
    main_coarse.a.a[:] = main.a.a[:, 0:main.order / coarsen,
                                  0:main.order / coarsen,
                                  0:main.order / coarsen]
    main_coarse.getRHS(main_coarse, eqns)
    Rnc = np.zeros(np.shape(main_coarse.RHS))
    Rnc[:] = main_coarse.RHS[:]

    main_qc = variables(main.Nel, main.order, main.quadpoints / 2, eqns,
                        main.mu, main.xG, main.yG, main.zG, main.t, main.et,
                        main.dt, main.iteration, main.save_freq, 'DNS',
                        main.procx, main.procy)
    main_qc.a.a[:] = main.a.a[:]
    main_qc.getRHS(main_qc, eqns)
    Rn_qc = np.zeros(np.shape(main_qc.RHS))
    Rn_qc[:] = main_qc.RHS[:]

    main_coarse2 = variables(main.Nel, main.order / coarsen2,
                             main.quadpoints / (2 * coarsen2), eqns, main.mu,
                             main.xG, main.yG, main.zG, main.t, main.et,
                             main.dt, main.iteration, main.save_freq, 'DNS',
                             main.procx, main.procy)
    main_coarse2.a.a[:] = main.a.a[:, 0:main.order / coarsen2,
                                   0:main.order / coarsen2,
                                   0:main.order / coarsen2]
    main_coarse2.getRHS(main_coarse2, eqns)
    Rnc2 = np.zeros(np.shape(main_coarse2.RHS))
    Rnc2[:] = main_coarse2.RHS[:]

    an = np.zeros(np.shape(main.a.a))
    an[:] = main.a.a[:]
    anc = np.zeros(np.shape(main_coarse.a.a))
    anc[:] = main_coarse.a.a[:]
    anc2 = np.zeros(np.shape(main_coarse2.a.a))
    anc2[:] = main_coarse2.a.a[:]

    NLiter = 0
    while (Rstar_glob >= 1e-8 and Rstar_glob / Rstar_glob0 > 1e-8):
        NLiter += 1

        def mv_coarse2(v1):
            vr = np.reshape(v1, np.shape(main_coarse2.a.a))
            eps = 5.e-2
            main_coarse2.a.a[:] = anc2[:] + eps * vr  #*filtarray
            main_coarse2.getRHS(main_coarse2, eqns)
            R1 = np.zeros(np.shape(main_coarse2.RHS))
            R1[:] = main_coarse2.RHS[:]
            Av = vr - main_coarse2.dt / 2. * (R1 - Rnc2) / eps
            return Av.flatten()

        def mv_coarse(v1):
            vr = np.reshape(v1, np.shape(main_coarse.a.a))
            eps = 5.e-2
            main_coarse.a.a[:] = anc[:] + eps * vr  #*filtarray
            main_coarse.getRHS(main_coarse, eqns)
            R1 = np.zeros(np.shape(main_coarse.RHS))
            R1[:] = main_coarse.RHS[:]
            Av = vr - main_coarse.dt / 2. * (R1 - Rnc) / eps
            return Av.flatten()

        def mv_qc(v):
            vr = np.reshape(v, np.shape(main_qc.a.a))
            eps = 5.e-2
            main_qc.a.a[:] = an[:] + eps * vr
            main_qc.getRHS(main_qc, eqns)
            R1 = np.zeros(np.shape(main.RHS))
            R1[:] = main_qc.RHS[:]
            Av = vr - main.dt / 2. * (R1 - Rn_qc) / eps
            return Av.flatten()

        def mv(v):
            vr = np.reshape(v, np.shape(main.a.a))
            eps = 5.e-2
            main.a.a[:] = an[:] + eps * vr
            main.getRHS(main, eqns)
            R1 = np.zeros(np.shape(main.RHS))
            R1[:] = main.RHS[:]
            Av = vr - main.dt / 2. * (R1 - Rn) / eps
            return Av.flatten()

        def mv_resid(mvf, v, b):
            return b - mvf(v)

        ts = time.time()
        #    sol = GMRes(mv, -Rstarn.flatten(), np.zeros(np.size(main.a.a)),main, tol=1e-6,maxiter_outer=1,maxiter=20, restart=None,printnorm=0)
        old[:] = 0.
        for i in range(0, 1):
            #      if (main.mpi_rank == 0): print('Fine Mesh')
            sol = GMRes(mv_qc,
                        -Rstarn.flatten(),
                        old.flatten(),
                        main,
                        tol=1e-5,
                        maxiter_outer=1,
                        maxiter=10,
                        restart=None,
                        printnorm=0)
            R = np.reshape(mv_resid(mv, sol, -Rstarn.flatten()),
                           np.shape(main.a.a))
            R_coarse = R[:, 0:main.order / coarsen, 0:main.order / coarsen,
                         0:main.order / coarsen]
            #      if (main.mpi_rank == 0):
            #        print('Running Coarse Mesh, time = ' + str(time.time() - ts))
            e = GMRes(mv_coarse,
                      R_coarse.flatten(),
                      np.zeros(np.shape(R_coarse.flatten())),
                      main,
                      tol=1e-6,
                      maxiter_outer=1,
                      maxiter=10,
                      restart=None,
                      printnorm=0)

            R1 = np.reshape(mv_resid(mv_coarse, e, R_coarse.flatten()),
                            np.shape(main_coarse.a.a))
            R_coarse2 = R1[:, 0:main.order / coarsen2, 0:main.order / coarsen2,
                           0:main.order / coarsen2]
            #
            e2 = GMRes(mv_coarse2,
                       R_coarse2.flatten(),
                       np.zeros(np.shape(R_coarse2.flatten())),
                       main,
                       tol=1e-6,
                       maxiter_outer=1,
                       maxiter=20,
                       restart=None,
                       printnorm=0)
            ##
            etmp = np.reshape(e, np.shape(main_coarse.a.a))
            etmp[:, 0:main.order / coarsen2, 0:main.order / coarsen2,
                 0:main.order / coarsen2] += np.reshape(
                     e2, np.shape(main_coarse2.a.a))
            e = GMRes(mv_coarse,
                      R_coarse.flatten(),
                      etmp.flatten(),
                      main,
                      tol=1e-6,
                      maxiter_outer=1,
                      maxiter=20,
                      restart=None,
                      printnorm=0)

            x0 = np.zeros(np.shape(main.a.a))
            x0[:] = np.reshape(sol, np.shape(main.a.a))
            x0[:, 0:main.order / coarsen, 0:main.order / coarsen,
               0:main.order /
               coarsen] = x0[:, 0:main.order / coarsen, 0:main.order / coarsen,
                             0:main.order / coarsen] + np.reshape(
                                 e, np.shape(main_coarse.a.a))
            old[:] = x0[:]

        sol = GMRes(mv_qc,
                    -Rstarn.flatten(),
                    old.flatten(),
                    main,
                    tol=1e-5,
                    maxiter_outer=1,
                    maxiter=30,
                    restart=None,
                    printnorm=0)

        main.a.a[:] = an[:] + np.reshape(sol, np.shape(main.a.a))  #*1.01
        Rstarn, Rn, Rstar_glob = unsteadyResid(main.a.a)
        an[:] = main.a.a[:]

        main_qc.a.a[:] = main.a.a[:]
        main_qc.getRHS(main_qc, eqns)
        Rn_qc[:] = main_qc.RHS[:]

        main_coarse.a.a[:] = main.a.a[:, 0:main.order / coarsen,
                                      0:main.order / coarsen,
                                      0:main.order / coarsen]
        main_coarse.getRHS(main_coarse, eqns)
        Rnc[:] = main_coarse.RHS[:]
        anc[:] = main_coarse.a.a[:]

        main_coarse2.a.a[:] = main.a.a[:, 0:main.order / coarsen2,
                                       0:main.order / coarsen2,
                                       0:main.order / coarsen2]
        main_coarse2.getRHS(main_coarse2, eqns)
        Rnc2[:] = main_coarse2.RHS[:]
        anc2[:] = main_coarse2.a.a[:]

        if (main.mpi_rank == 0):
            print(
                'NL iteration = ' + str(NLiter) + '  NL residual = ' +
                str(Rstar_glob),
                ' relative decrease = ' + str(Rstar_glob / Rstar_glob0),
                ' Solve time = ' + str(time.time() - ts))

    main.t += main.dt
    main.iteration += 1
Пример #4
0
def newtonSolver_MG2(unsteadyResidual,MF_Jacobian,main,linear_solver,sparse_quadrature,eqns):
  coarsen = 2
  coarsen2 = 4
  eqns2 = equations('Navier-Stokes',('roe','Inviscid'))
  main_coarse = variables(main.Nel,main.order/coarsen,main.quadpoints/(2*coarsen),eqns2,main.mu,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,'DNS',main.procx,main.procy)
  main_qc = variables(main.Nel,main.order,main.quadpoints/2,eqns2,main.mu,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,'DNS',main.procx,main.procy)
  main_coarse2 = variables(main.Nel,main.order/coarsen2,main.quadpoints/(2*coarsen2),eqns2,main.mu,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,'DNS',main.procx,main.procy)

  Rnc = np.zeros(np.shape(main_coarse.RHS))
  Rn_qc = np.zeros(np.shape(main_qc.RHS))
  Rnc2 = np.zeros(np.shape(main_coarse2.RHS))
  anc = np.zeros(np.shape(main_coarse.a.a))
  anc2 = np.zeros(np.shape(main_coarse2.a.a))

  def newtonHook(main,main_coarse,main_qc):
    main_coarse.a.a[:] = main.a.a[:,0:main.order[0]/coarsen,0:main.order[1]/coarsen,0:main.order[2]/coarsen]
    main_coarse.getRHS(main_coarse,eqns)
    Rnc[:] = main_coarse.RHS[:]
 
    main_qc.a.a[:] = main.a.a[:]
    main_qc.getRHS(main_qc,eqns)
    Rn_qc[:] = main_qc.RHS[:]
    anc[:] = main_coarse.a.a[:]
 
    main_coarse2.a.a[:] = main.a.a[:,0:main.order[0]/coarsen2,0:main.order[1]/coarsen2,0:main.order[2]/coarsen2]
    main_coarse2.getRHS(main_coarse2,eqns)
    Rnc2[:] = main_coarse2.RHS[:]
    anc2[:] = main_coarse2.a.a[:]


  def mv_resid(MF_Jacobian,args,main,v,b):
    return b - MF_Jacobian(v,args,main)

  Rstarn,Rn,Rstar_glob = unsteadyResidual(main.a.a)
  NLiter = 0
  an = np.zeros(np.shape(main.a0))
  an[:] = main.a0[:]
  Rstar_glob0 = Rstar_glob*1.
  old = np.zeros(np.shape(main.a.a))
  while (Rstar_glob >= 1e-8 and Rstar_glob/Rstar_glob0 > 1e-8):
    NLiter += 1
    ts = time.time()
    old[:] = 0.
    newtonHook(main,main_coarse,main_qc)
    for i in range(0,1):
      #run the solution on the fine mesh (probably with sparse quadrature)
      MF_Jacobian_args = [an,Rn_qc]
      sol = linear_solver.solve(MF_Jacobian,-Rstarn.flatten(), old.flatten(),main_qc,MF_Jacobian_args,tol=1e-5,maxiter_outer=1,maxiter=10,printnorm=0)
      # restrict
      R =  np.reshape( mv_resid(MF_Jacobian,MF_Jacobian_args,main_qc,sol,-Rstarn.flatten()) , np.shape(main.a.a ) )
      R_coarse = R[:,0:main.order[0]/coarsen,0:main.order[1]/coarsen,0:main.order[2]/coarsen]
      # solve for the error on the coarse mesh
      MF_Jacobian_argsc = [anc,Rnc]
      e = linear_solver.solve(MF_Jacobian,R_coarse.flatten(), np.zeros(np.shape(R_coarse.flatten())),main_coarse,MF_Jacobian_argsc,tol=1e-6,maxiter_outer=1,maxiter=30,printnorm=0)
      R1 =  np.reshape( mv_resid(MF_Jacobian,MF_Jacobian_argsc,main_coarse,e,R_coarse.flatten()) , np.shape(main_coarse.a.a ) )
      R_coarse2 = R1[:,0:main.order[0]/coarsen2,0:main.order[1]/coarsen2,0:main.order[2]/coarsen2]
      ##
      MF_Jacobian_argsc2 = [anc2,Rnc2]
      e2 = linear_solver.solve(MF_Jacobian,R_coarse2.flatten(),np.zeros(np.size(R_coarse2)),main_coarse2,MF_Jacobian_argsc2,tol=1e-5,maxiter_outer=1,maxiter=30,printnorm=0)
      ###
      etmp = np.reshape(e,np.shape(main_coarse.a.a))
      etmp[:,0:main.order[0]/coarsen2,0:main.order[1]/coarsen2,0:main.order[2]/coarsen2] += np.reshape(e2,np.shape(main_coarse2.a.a))
      e = linear_solver.solve(MF_Jacobian,R_coarse.flatten(),etmp.flatten(),main_coarse,MF_Jacobian_argsc,tol=1e-6,maxiter_outer=1,maxiter=30,printnorm=0)

      old[:] = np.reshape(sol,np.shape(main.a.a))
      old[:,0:main.order[0]/coarsen,0:main.order[1]/coarsen,0:main.order[2]/coarsen] += np.reshape( e , np.shape(main_coarse.a.a) )

    # Run the final iterations on the fine mesh
    #sol = linear_solver.solve(MF_Jacobian, -Rstarn.flatten(), np.zeros(np.size(main.a.a)),main_qc,MF_Jacobian_args, linear_solver.tol,linear_solver.maxiter_outer,linear_solver.maxiter,linear_solver.printnorm)
    sol = linear_solver.solve(MF_Jacobian, -Rstarn.flatten(), old.flatten(),main_qc,MF_Jacobian_args, 1e-5,1,30,linear_solver.printnorm)

    main.a.a[:] = an[:] + np.reshape(sol,np.shape(main.a.a))
    an[:] = main.a.a[:]
    Rstarn,Rn,Rstar_glob = unsteadyResidual(main.a.a)
    if (main.mpi_rank == 0):
      sys.stdout.write('NL iteration = ' + str(NLiter) + '  NL residual = ' + str(Rstar_glob) + ' relative decrease = ' + str(Rstar_glob/Rstar_glob0) + ' Solve time = ' + str(time.time() - ts)  + '\n')
      sys.stdout.flush()
Пример #5
0
def advanceSolImplicit_MYNKPC(main, MZ, eqns):
    main.a0[:] = main.a.a[:]
    main.getRHS(main, eqns)
    R0 = np.zeros(np.shape(main.RHS))
    R0[:] = main.RHS[:]

    def unsteadyResid(v):
        main.a.a[:] = np.reshape(v, np.shape(main.a.a))
        main.getRHS(main, eqns)
        R1 = np.zeros(np.shape(main.RHS))
        R1[:] = main.RHS[:]
        #Rstar = np.reshape( (v.flatten() - main.a0.flatten() ) - 0.5*main.dt*(R0 + R1).flatten() , np.shape(main.a.a))
        Rstar = (main.a.a[:] - main.a0) - 0.5 * main.dt * (R0 + R1)
        ## Create Global residual
        data = main.comm.gather(np.linalg.norm(Rstar)**2, root=0)
        if (main.mpi_rank == 0):
            Rstar_glob = 0.
            for j in range(0, main.num_processes):
                Rstar_glob += data[j]
            Rstar_glob = np.sqrt(Rstar_glob)
            for j in range(1, main.num_processes):
                main.comm.send(Rstar_glob, dest=j)
        else:
            Rstar_glob = main.comm.recv(source=0)
        return Rstar, R1, Rstar_glob

    Rstarn, Rn, Rstar_glob = unsteadyResid(main.a.a)
    NLiter = 0
    an = np.zeros(np.shape(main.a0))
    an[:] = main.a0[:]
    Rstar_glob0 = Rstar_glob * 1.
    if (main.mpi_rank == 0):
        print(
            'NL iteration = ' + str(NLiter) + '  NL residual = ' +
            str(Rstar_glob),
            ' relative decrease = ' + str(Rstar_glob / Rstar_glob0))

    coarsen = 2
    coarsen2 = 1
    old = np.zeros(np.size(main.a.a))
    coarsen_f = 1
    Rstar_glob0 = Rstar_glob * 1.
    main_coarse = variables(main.Nel, main.order, main.quadpoints / (coarsen),
                            eqns, main.mu, main.xG, main.yG, main.zG, main.t,
                            main.et, main.dt, main.iteration, main.save_freq,
                            'DNS', main.procx, main.procy)
    filtarray = np.zeros(np.shape(main.a.a))
    filtarray[:, 0:main.order / coarsen_f, 0:main.order / coarsen_f,
              0:main.order / coarsen_f] = 1.
    main_coarse.a.a[:] = main.a.a[:]
    main_coarse.getRHS(main_coarse, eqns)
    Rnc = np.zeros(np.shape(main_coarse.RHS))
    Rnc[:] = main_coarse.RHS[:]

    #main_coarse2 = variables(main.Nel,main.order,main.quadpoints/(coarsen2),eqns,main.mu*0,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,'DNS',main.procx,main.procy)
    #main_coarse2.a.a[:] = main.a.a[:]

    NLiter = 0
    an = np.zeros(np.shape(main.a0))
    an[:] = main.a0[:]
    while (Rstar_glob >= 1e-8 and Rstar_glob / Rstar_glob0 > 1e-8):
        NLiter += 1

        def mv_coarse2(v1):
            vr = np.reshape(v1, np.shape(main_coarse.a.a))
            eps = 5e-2
            main_coarse2.a.a[:] = an[:] * filtarray
            main_coarse2.getRHS(main_coarse2, eqns)

            Rn = np.zeros(np.shape(main_coarse2.RHS))
            Rn[:] = main_coarse2.RHS[:]
            main_coarse2.a.a[:] = an[:] * filtarray + eps * vr  #*filtarray
            main_coarse2.getRHS(main_coarse2, eqns)
            R1 = np.zeros(np.shape(main_coarse2.RHS))
            R1[:] = main_coarse2.RHS[:]
            Av = vr - main_coarse.dt / 2. * (R1 - Rn) / eps
            return Av.flatten()

        def mv_coarse(v1):
            #y = GMRes(mv_coarse2,v1, 0*np.ones(np.size(main.a.a)),main, tol=1e-5,maxiter_outer=1,maxiter=10, restart=None,printnorm=0)
            #vr = np.reshape(y,np.shape(main_coarse.a.a))

            vr = np.reshape(v1, np.shape(main.a.a))
            eps = 5.e-2
            #main_coarse.a.a[:] = an[:]*filtarray
            #main_coarse.getRHS(main_coarse,eqns)
            #Rn = np.zeros(np.shape(main_coarse.RHS))
            #Rn[:] = main_coarse.RHS[:]

            main_coarse.a.a[:] = an[:] * filtarray + eps * vr  #*filtarray
            main_coarse.getRHS(main_coarse, eqns)
            R1 = np.zeros(np.shape(main_coarse.RHS))
            R1[:] = main_coarse.RHS[:]
            Av = vr - main_coarse.dt / 2. * (R1 - Rnc) / eps
            return Av.flatten()

        def mv2(v):
            vr = np.reshape(v, np.shape(main.a.a))
            eps = 5.e-2
            main.a.a[:] = an[:] + eps * vr
            main.getRHS(main, eqns)
            R1 = np.zeros(np.shape(main.RHS))
            R1[:] = main.RHS[:]
            Av = vr - main.dt / 2. * (R1 - Rn) / eps
            return Av.flatten()

        def mv(v):
            y = GMRes(mv_coarse,
                      v,
                      0. * np.ones(np.size(main.a.a)),
                      main,
                      tol=1e-7,
                      maxiter_outer=1,
                      maxiter=120,
                      restart=None,
                      printnorm=0)
            #w = GMRes(mv_coarse,v, 1.e-20*np.ones(np.size(main.a.a)),main, tol=1e-5,maxiter_outer=1,maxiter=40, restart=None,printnorm=1)
            #y = GMRes(mv_coarse2,w, 1.e-20*np.ones(np.size(main.a.a)),main, tol=1e-5,maxiter_outer=1,maxiter=40, restart=None,printnorm=1)
            vr = np.reshape(y, np.shape(main.a.a))
            eps = 5.e-2
            main.a.a[:] = an[:] + eps * vr
            main.getRHS(main, eqns)
            R1 = np.zeros(np.shape(main.RHS))
            R1[:] = main.RHS[:]
            Av = vr - main.dt / 2. * (R1 - Rn) / eps
            return Av.flatten()

        ts = time.time()
        #w = GMRes(mv, -Rstarn.flatten(), np.ones(np.size(main.a.a))*1.e-10,main, tol=1e-8,maxiter_outer=1,maxiter=5, restart=None,printnorm=1)
        #sol = GMRes(mv_coarse,w, np.ones(np.size(main.a.a))*0.,main, tol=1e-7,maxiter_outer=1,maxiter=120, restart=None,printnorm=1)
        sol = GMRes(mv_coarse,
                    -Rstarn.flatten(),
                    old * 0.,
                    main,
                    tol=1e-6,
                    maxiter_outer=1,
                    maxiter=40,
                    restart=None,
                    printnorm=0)
        old[:] = sol[:]
        #sol = GMRes(mv_coarse
        main.a.a[:] = an[:] + np.reshape(sol, np.shape(main.a.a))  #*1.01
        Rstarn, Rn, Rstar_glob = unsteadyResid(main.a.a)
        an[:] = main.a.a[:]
        #main_coarse.a.a[:] = main.a.a[:]

        main_coarse.a.a[:] = main.a.a[:]
        main_coarse.getRHS(main_coarse, eqns)
        Rnc[:] = main_coarse.RHS[:]
        if (main.mpi_rank == 0):
            print(
                'NL iteration = ' + str(NLiter) + '  NL residual = ' +
                str(Rstar_glob),
                ' relative decrease = ' + str(Rstar_glob / Rstar_glob0),
                ' Solve time = ' + str(time.time() - ts))

    main.t += main.dt
    main.iteration += 1
Пример #6
0
def newtonSolver(unsteadyResidual, MF_Jacobian, main, linear_solver,
                 sparse_quadrature, eqns):
    if (sparse_quadrature):
        coarsen = 2
        quadpoints_coarsen = np.fmax(main.quadpoints / (coarsen), 1)
        quadpoints_coarsen[-1] = main.quadpoints[-1]
        main_coarse = variables(main.Nel, main.order, quadpoints_coarsen, eqns,
                                main.mus, main.xG, main.yG, main.zG, main.t,
                                main.et, main.dt, main.iteration,
                                main.save_freq, 'DNS', main.procx, main.procy,
                                main.BCs, main.fsource, main.source_mag,
                                main.shock_capturing, main.mol_str)
        main_coarse.basis = main.basis
        main_coarse.a.a[:] = main.a.a[:]

        def newtonHook(main_coarse, main, Rn):
            main_coarse.a.a[:] = main.a.a[:]
            main_coarse.getRHS(main_coarse, main_coarse, eqns)
            #getRHS_SOURCE(main_coarse,main_coarse,eqns)
            Rn[:] = main_coarse.RHS[:]
    else:
        main_coarse = main

        def newtonHook(main_coarse, main, Rn):
            pass

    Rstarn, Rn, Rstar_glob = unsteadyResidual(main.a.a)
    NLiter = 0
    an = np.zeros(np.shape(main.a0))
    an[:] = main.a0[:]
    Rstar_glob0 = Rstar_glob * 1.
    old = np.zeros(np.shape(main.a.a))
    resid_hist = np.zeros(0)
    t_hist = np.zeros(0)
    tnls = time.time()
    while (Rstar_glob >= 1e-8 and Rstar_glob / Rstar_glob0 > 1e-8):
        NLiter += 1
        ts = time.time()
        newtonHook(main_coarse, main, Rn)
        MF_Jacobian_args = [an, Rn]
        delta = 1
        #    if (Rstar_glob/Rstar_glob0 < 1e-4):
        #      delta = 2
        #    if (Rstar_glob/Rstar_glob0 < 1e-5):
        #      delta = 3
        #    if (Rstar_glob/Rstar_glob0 < 1e-6):
        #      delta = 3
        sol = linear_solver.solve(MF_Jacobian, -Rstarn.flatten(),
                                  old.flatten(), main_coarse, MF_Jacobian_args,
                                  np.fmin(Rstar_glob, 0.1),
                                  linear_solver.maxiter_outer, 20, False)
        main.a.a[:] = an[:] + 1.0 * np.reshape(sol, np.shape(main.a.a))
        an[:] = main.a.a[:]
        Rstarn, Rn, Rstar_glob = unsteadyResidual(main.a.a)
        resid_hist = np.append(resid_hist, Rstar_glob)
        t_hist = np.append(t_hist, time.time() - tnls)
        if (main.mpi_rank == 0):
            sys.stdout.write('NL iteration = ' + str(NLiter) +
                             '  NL residual = ' + str(Rstar_glob) +
                             ' relative decrease = ' +
                             str(Rstar_glob / Rstar_glob0) + ' Solve time = ' +
                             str(time.time() - ts) + '\n')
            #print(np.linalg.norm(Rstarn[0]),np.linalg.norm(Rstarn[-1]))

            sys.stdout.flush()
    np.savez('resid_history', resid=resid_hist, t=t_hist)
Пример #7
0
def newtonSolver_PC8(unsteadyResidual, MF_Jacobian, main, linear_solver,
                     sparse_quadrature, eqns):
    order_coarsen = np.fmax(main.order / 2, 1)
    #  order_coarsen[-1] = main.order[-1]
    quadpoints_coarsen = np.fmax(main.quadpoints / 2, 1)
    quadpoints_coarsen[-1] = main.quadpoints[-1]
    main_coarse = variables(main.Nel, order_coarsen, quadpoints_coarsen, eqns,
                            main.mus, main.xG, main.yG, main.zG, main.t,
                            main.et, main.dt, main.iteration, main.save_freq,
                            'DNS', main.procx, main.procy, main.BCs,
                            main.fsource, main.source_mag,
                            main.shock_capturing)
    main_coarse.basis = main.basis
    main_coarse.a.a[:] = main.a.a[:, 0:main_coarse.order[0],
                                  0:main_coarse.order[1],
                                  0:main_coarse.order[2],
                                  0:main_coarse.order[3]]

    def newtonHook(main, main_coarse, Rn, Rnc):
        eqns.getRHS(main, main, eqns)
        Rn[:] = main.RHS[:]
        eqns.getRHS(main_coarse, main_coarse, eqns)
        Rnc[:] = main_coarse.RHS[:]

    def Minv(v, main, main_coarse, MF_Jacobian_args, MF_Jacobian_args2):
        def mv_resid(MF_Jacobian, args, main, v, b):
            return b - MF_Jacobian(v, args, main)

        coarse_order = np.shape(main_coarse.a.a)[1:5]
        old = np.zeros(np.shape(main.a.a))
        for i in range(0, 1):
            # solve on the fine mesh
            sol = linear_solver.solvePC(MF_Jacobian,
                                        v.flatten() * 1., old.flatten(), main,
                                        MF_Jacobian_args2, 1e-6,
                                        linear_solver.maxiter_outer, 7, False)

            # restrict
            R = np.reshape(
                mv_resid(MF_Jacobian, MF_Jacobian_args2, main, sol,
                         v.flatten()), np.shape(main.a.a))
            R_coarse = R[:, 0:order_coarsen[0], 0:order_coarsen[1],
                         0:order_coarsen[2], 0:order_coarsen[3]]
            # solve for the error on the coarse mesh
            e = linear_solver.solvePC(MF_Jacobian, R_coarse.flatten(),
                                      np.zeros(np.shape(R_coarse.flatten())),
                                      main_coarse, MF_Jacobian_args, 1e-6,
                                      linear_solver.maxiter_outer, 1, False)
            #
            old = np.zeros(np.shape(main.a.a))
            old[:] = np.reshape(sol, np.shape(main.a.a))
            old[:, 0:order_coarsen[0], 0:order_coarsen[1], 0:order_coarsen[2],
                0:order_coarsen[3]] += np.reshape(e, np.shape(main_coarse.a.a))

            # Run the final iterations on the fine mesh
            sol = linear_solver.solvePC(MF_Jacobian, v.flatten(),
                                        old.flatten(), main, MF_Jacobian_args2,
                                        1e-6, linear_solver.maxiter_outer, 7,
                                        False)

#    Minv_v = np.zeros(np.shape(main.a.a))
#    Minv_v[:] = np.reshape(v,np.shape(main.a.a))
#    tmp_coarse = Minv_v[:,0:coarse_order[0],0:coarse_order[1],0:coarse_order[2],0:coarse_order[3]]
#    Minv_v2 = np.zeros(np.shape(main.a.a))
#    Minv_v2[:] = Minv_v[:]
#    tmp_coarse2 = np.zeros(np.shape(tmp_coarse))
#    tmp_coarse2[:] = tmp_coarse[:]
#    tmp_coarse = linear_solver.solvePC(MF_Jacobian, tmp_coarse2.flatten(), tmp_coarse2.flatten()*0.,main_coarse,MF_Jacobian_args, 1e-6,linear_solver.maxiter_outer,10,False)
#    Minv_v[:,0:coarse_order[0],0:coarse_order[1],0:coarse_order[2],0:coarse_order[3]] = np.reshape(tmp_coarse[:],np.shape(main_coarse.a.a))
#    sol = linear_solver.solvePC(MF_Jacobian, v2.flatten(), Minv_v.flatten()*1.,main,MF_Jacobian_args2, 1e-6,linear_solver.maxiter_outer,20,False)
#
#
#    plt.plot( np.reshape(tmp_coarse[:],np.shape(main_coarse.a.a))[0,:,0,0,0,0,0,0,0])
#    plt.plot( np.reshape(tmp_coarse1[:],np.shape(main.a.a))[0,:,0,0,0,0,0,0,0])
#    plt.pause(0.01)
#    plt.clf()

        return sol.flatten()

    Rstarn, Rn, Rstar_glob = unsteadyResidual(main.a.a)
    NLiter = 0
    an = np.zeros(np.shape(main.a0))
    an[:] = main.a0[:]
    Rnc = np.zeros(np.shape(main_coarse.a0))
    anc = np.zeros(np.shape(main_coarse.a0))
    anc[:] = main.a0[:, 0:main_coarse.order[0], 0:main_coarse.order[1],
                     0:main_coarse.order[2], 0:main_coarse.order[3]]
    Rstar_glob0 = Rstar_glob * 1.
    while (Rstar_glob >= 1e-20 and Rstar_glob / Rstar_glob0 > 1e-9):
        NLiter += 1
        ts = time.time()
        newtonHook(main, main_coarse, Rn, Rnc)
        MF_Jacobian_args = [an, Rn]
        MF_Jacobian_args_coarse = [anc, Rnc]
        delta = 1

        sol = linear_solver.solve(MF_Jacobian, -Rstarn.flatten(),
                                  np.zeros(np.size(main.a.a)), main,
                                  MF_Jacobian_args, main_coarse,
                                  MF_Jacobian_args_coarse, Minv,
                                  linear_solver.tol,
                                  linear_solver.maxiter_outer, 10, False)
        main.a.a[:] = an[:] + np.reshape(sol, np.shape(main.a.a))
        an[:] = main.a.a[:]
        anc[:] = an[:, 0:main_coarse.order[0], 0:main_coarse.order[1],
                    0:main_coarse.order[2], 0:main_coarse.order[3]]
        main_coarse.a.a[:] = main.a.a[:, 0:main_coarse.order[0],
                                      0:main_coarse.order[1],
                                      0:main_coarse.order[2],
                                      0:main_coarse.order[3]]

        Rstarn, Rn, Rstar_glob = unsteadyResidual(main.a.a)
        if (main.mpi_rank == 0):
            sys.stdout.write('NL iteration = ' + str(NLiter) +
                             '  NL residual = ' + str(Rstar_glob) +
                             ' relative decrease = ' +
                             str(Rstar_glob / Rstar_glob0) + ' Solve time = ' +
                             str(time.time() - ts) + '\n')
            sys.stdout.flush()
Пример #8
0
def newtonSolver_PC2(unsteadyResidual, MF_Jacobian, main, linear_solver,
                     sparse_quadrature, eqns):
    if (sparse_quadrature):
        coarsen = 2
        quadpoints_coarsen = np.fmax(main.quadpoints / (coarsen), 1)
        quadpoints_coarsen[-1] = main.quadpoints[-1]
        main_coarse = variables(main.Nel, main.order, quadpoints_coarsen, eqns,
                                main.mus, main.xG, main.yG, main.zG, main.t,
                                main.et, main.dt, main.iteration,
                                main.save_freq, 'DNS', main.procx, main.procy,
                                main.BCs, main.fsource, main.source_mag,
                                main.shock_capturing)
        main_coarse.basis = main.basis
        main_coarse.a.a[:] = main.a.a[:]

        def newtonHook(main_coarse, main, Rn):
            main_coarse.a.a[:] = main.a.a[:]
            main_coarse.getRHS(main_coarse, main_coarse, eqns)
            Rn[:] = main_coarse.RHS[:]
    else:
        main_coarse = main

        def newtonHook(main_coarse, main, Rn):
            pass

    Rstarn, Rn, Rstar_glob = unsteadyResidual(main.a.a)
    NLiter = 0
    an = np.zeros(np.shape(main.a0))
    an[:] = main.a0[:]
    Rstar_glob0 = Rstar_glob * 1.
    old = np.zeros(np.shape(main.a.a))

    def Minv(v, main, MF_Jacobian, MF_Jacobian_args, k):
        sol = linear_solver.solvePC(MF_Jacobian,
                                    v.flatten() * 1.,
                                    v.flatten() * 0., main, MF_Jacobian_args,
                                    1e-6, linear_solver.maxiter_outer, 5,
                                    False)
        return sol.flatten()

    while (Rstar_glob >= 1e-20 and Rstar_glob / Rstar_glob0 > 1e-9):
        NLiter += 1
        ts = time.time()
        newtonHook(main_coarse, main, Rn)
        MF_Jacobian_args = [an, Rn]
        delta = 1
        sol = linear_solver.solve(MF_Jacobian, -Rstarn.flatten(),
                                  np.zeros(np.size(main_coarse.a.a)),
                                  main_coarse, MF_Jacobian_args, Minv,
                                  linear_solver.tol,
                                  linear_solver.maxiter_outer, 10, False)

        main.a.a[:] = an[:] + np.reshape(sol, np.shape(main.a.a))
        an[:] = main.a.a[:]

        Rstarn, Rn, Rstar_glob = unsteadyResidual(main.a.a)
        if (main.mpi_rank == 0):
            sys.stdout.write('NL iteration = ' + str(NLiter) +
                             '  NL residual = ' + str(Rstar_glob) +
                             ' relative decrease = ' +
                             str(Rstar_glob / Rstar_glob0) + ' Solve time = ' +
                             str(time.time() - ts) + '\n')
            sys.stdout.flush()
Пример #9
0
def fractionalStep(main, MZ, eqns, args):
    ord_arr0 = np.linspace(0, main.order[0] - 1, main.order[0])
    ord_arr1 = np.linspace(0, main.order[1] - 1, main.order[1])
    ord_arr2 = np.linspace(0, main.order[2] - 1, main.order[2])
    ord_arr3 = np.linspace(0, main.order[3] - 1, main.order[3])
    scale = (2. * ord_arr0[:, None, None, None] +
             1.) * (2. * ord_arr1[None, :, None, None] +
                    1.) * (2. * ord_arr2[None, None, :, None] + 1.) * (
                        2. * ord_arr3[None, None, None, :] + 1.) / 16.

    nonlinear_solver = args[0]
    linear_solver = args[1]
    sparse_quadrature = args[2]
    pressure_linear_solver = args[3]
    main.a0[:] = main.a.a[:]
    eqns.getRHS(main, main, eqns)
    R0 = np.zeros(np.shape(main.RHS))
    R0[:] = main.RHS[:]

    def unsteadyResidual(v):
        main.a.a[:] = np.reshape(v, np.shape(main.a.a))
        eqns.getRHS(main, main, eqns)
        R1 = np.zeros(np.shape(main.RHS))
        R1[:] = main.RHS[:]
        Rstar = (main.a.a[:] - main.a0) - 0.5 * main.dt * (R0 + R1)
        Rstar_glob = gatherResid(Rstar, main)
        return Rstar, R1, Rstar_glob

    def create_MF_Jacobian(v, args, main):
        an = args[0]
        Rn = args[1]
        vr = np.reshape(v, np.shape(main.a.a))
        eps = 5.e-2
        main.a.a[:] = an + eps * vr
        eqns.getRHS(main, main, eqns)
        R1 = np.zeros(np.shape(main.RHS))
        R1[:] = main.RHS[:]
        Av = vr - main.dt / 2. * (R1 - Rn) / eps
        return Av.flatten()

    # solve for velocity
    nonlinear_solver.solve(unsteadyResidual, create_MF_Jacobian, main,
                           linear_solver, sparse_quadrature, eqns)

    # now we need to solve for the pressure correction

    right_bc = 'neumann'
    left_bc = 'neumann'
    top_bc = 'neumann'
    bottom_bc = 'neumann'
    #right_bc = 'dirichlet'
    #left_bc = 'dirichlet'
    #top_bc = 'dirichlet'
    #bottom_bc = 'dirichlet'

    right_bc_args = [0]
    left_bc_args = [0]
    top_bc_args = [0]
    bottom_bc_args = [0]
    BCs = [
        right_bc, right_bc_args, top_bc, top_bc_args, left_bc, left_bc_args,
        bottom_bc, bottom_bc_args
    ]

    eqnsPoisson = equations('Diffusion', ('central', 'BR1'), 'none')
    poisson_main = variables(main.Nel,main.order,main.quadpoints,eqnsPoisson,1,main.xG,main.yG,main.zG,main.t,main.et,main.dt,main.iteration,main.save_freq,main.turb_str,main.procx,main.procy,\
                           main.BCs,None,0,False,False)
    main.a.Upx, main.a.Upy, main.a.Upz = main.basis.diffU(main.a.a, main)
    div = main.a.Upx[0] + main.a.Upy[1] + main.a.Upz[2]
    #div = div - np.mean(div)
    print('Start div = ', np.linalg.norm(div), np.sum(div))
    force = (div) / main.dt
    source = main.basis.volIntegrateGlob(
        poisson_main, force, poisson_main.w0, poisson_main.w1, poisson_main.w2,
        poisson_main.w3) * scale[None, :, :, :, :, None, None, None, None]
    print(np.shape(force))
    div_int = np.sum(source)
    vol_int = main.basis.volIntegrateGlob(
        poisson_main, np.ones(np.shape(force)), poisson_main.w0,
        poisson_main.w1, poisson_main.w2,
        poisson_main.w3) * scale[None, :, :, :, :, None, None, None, None]
    vol_int = np.sum(vol_int)
    #  print(np.sum(source2))
    #  difference = (np.sum(source) )/(2.*np.pi)**3
    source = main.basis.volIntegrateGlob(
        poisson_main, force - div_int / vol_int, poisson_main.w0,
        poisson_main.w1, poisson_main.w2,
        poisson_main.w3) * scale[None, :, :, :, :, None, None, None, None]
    print(np.sum(source))

    def unsteadyResidual_poisson(v):
        poisson_main.a.a[:] = np.reshape(v[:], np.shape(poisson_main.a.a))
        eqnsPoisson.getRHS(poisson_main, poisson_main, eqnsPoisson)
        R1 = np.zeros(np.shape(poisson_main.RHS))
        R1[:] = poisson_main.RHS[:]
        Rstar = R1 - source
        Rstar_glob = gatherResid(Rstar, poisson_main)
        Rstar = Rstar.flatten()
        return Rstar, R1, Rstar_glob

    def create_MF_Jacobian_poisson(v, args, poisson_main):
        vr = np.reshape(v[:], np.shape(poisson_main.a.a))
        poisson_main.a.a[:] = vr
        eqnsPoisson.getRHS(poisson_main, poisson_main, eqnsPoisson)
        R1 = np.zeros(np.shape(poisson_main.RHS))
        R1[:] = poisson_main.RHS[:]
        Av = (R1).flatten()
        return Av.flatten()

    nonlinear_solver.solve(unsteadyResidual_poisson,
                           create_MF_Jacobian_poisson, poisson_main,
                           linear_solver, False, eqnsPoisson)
    #  v = np.zeros(np.size(poisson_main.a.a))
    #  v[:] = poisson_main.a.a.flatten()
    #  Rstarn,Rn,Rstar_glob = unsteadyResidual_poisson(v)
    #  old = np.zeros(np.size(poisson_main.a.a))
    #  sol = pressure_linear_solver.solve(create_MF_Jacobian_poisson, -Rstarn.flatten(), old.flatten(),poisson_main,[],1e-7,linear_solver.maxiter_outer,500,True)
    #  poisson_main.a.a[:] = np.reshape(sol[:],np.shape(poisson_main.a.a))
    ## Now fix velocity
    px, py, pz = poisson_main.basis.diffU(poisson_main.a.a, poisson_main)
    main.a.u[0] = main.a.u[0] - main.dt * px
    main.a.u[1] = main.a.u[1] - main.dt * py
    main.a.u[2] = main.a.u[2] - main.dt * pz
    main.a.a[:] = main.basis.volIntegrateGlob(
        main, main.a.u, main.w0, main.w1, main.w2,
        main.w3) * scale[None, :, :, :, :, None, None, None, None]
    main.a.Upx, main.a.Upy, main.a.Upz = main.basis.diffU(main.a.a, main)
    div = main.a.Upx[0] + main.a.Upy[1] + main.a.Upz[2]
    print('End div = ', np.linalg.norm(div))
    main.t += main.dt
    main.iteration += 1
    main.a.p[:] = poisson_main.a.u[0]