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test_oldroydb.py
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test_oldroydb.py
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from lbmpy.updatekernels import create_stream_pull_with_output_kernel
from lbmpy import create_lb_update_rule, relaxation_rate_from_lattice_viscosity, ForceModel, Method, LBStencil
from lbmpy.macroscopic_value_kernels import macroscopic_values_setter
from pystencils.boundaries.boundaryhandling import BoundaryHandling
from pystencils.boundaries.boundaryconditions import Neumann, Dirichlet
from lbmpy.boundaries.boundaryhandling import LatticeBoltzmannBoundaryHandling
from lbmpy.boundaries import NoSlip
from lbmpy.oldroydb import *
import pytest
# # Lattice Boltzmann with Finite-Volume Oldroyd-B
# # taken from the electronic supplement of https://doi.org/10.1140/epje/s10189-020-00005-6,
# # available at https://doi.org/10.24416/UU01-2AFZSW
pytest.importorskip('scipy.optimize')
def test_oldroydb():
import scipy.optimize
# ## Definitions
L = (34, 34)
lambda_p = sp.Symbol("lambda_p")
eta_p = sp.Symbol("eta_p")
lb_stencil = LBStencil("D2Q9")
fv_stencil = LBStencil("D2Q9")
eta = 1 - eta_p
omega = relaxation_rate_from_lattice_viscosity(eta)
f_pre = 0.00001
# ## Data structures
dh = ps.create_data_handling(L, periodicity=(True, False), default_target=ps.Target.CPU)
opts = {'cpu_openmp': False,
'cpu_vectorize_info': None,
'target': dh.default_target}
src = dh.add_array('src', values_per_cell=len(lb_stencil), layout='c')
dst = dh.add_array_like('dst', 'src')
ρ = dh.add_array('rho', layout='c', latex_name='\\rho')
u = dh.add_array('u', values_per_cell=dh.dim, layout='c')
tauface = dh.add_array('tau_face', values_per_cell=(len(fv_stencil) // 2, dh.dim, dh.dim), latex_name='\\tau_f',
field_type=ps.FieldType.STAGGERED, layout='c')
tau = dh.add_array('tau', values_per_cell=(dh.dim, dh.dim), layout='c', latex_name='\\tau')
tauflux = dh.add_array('j_tau', values_per_cell=(len(fv_stencil) // 2, dh.dim, dh.dim), latex_name='j_\\tau',
field_type=ps.FieldType.STAGGERED_FLUX, layout='c')
F = dh.add_array('F', values_per_cell=dh.dim, layout='c')
fluxbh = BoundaryHandling(dh, tauflux.name, fv_stencil, name="flux_boundary_handling",
openmp=opts['cpu_openmp'], target=dh.default_target)
ubh = BoundaryHandling(dh, u.name, lb_stencil, name="velocity_boundary_handling",
openmp=opts['cpu_openmp'], target=dh.default_target)
taufacebh = BoundaryHandling(dh, tauface.name, fv_stencil, name="tauface_boundary_handling",
openmp=opts['cpu_openmp'], target=dh.default_target)
# ## Solver
collision = create_lb_update_rule(stencil=lb_stencil,
method=Method.TRT,
relaxation_rate=omega,
compressible=True,
force_model=ForceModel.GUO,
force=F.center_vector + sp.Matrix([f_pre, 0]),
kernel_type='collide_only',
optimization={'symbolic_field': src})
stream = create_stream_pull_with_output_kernel(collision.method, src, dst, {'density': ρ, 'velocity': u})
lbbh = LatticeBoltzmannBoundaryHandling(collision.method, dh, src.name,
openmp=opts['cpu_openmp'], target=dh.default_target)
stream_kernel = ps.create_kernel(stream, **opts).compile()
collision_kernel = ps.create_kernel(collision, **opts).compile()
ob = OldroydB(dh.dim, u, tau, F, tauflux, tauface, lambda_p, eta_p)
flux_kernel = ps.create_staggered_kernel(ob.flux(), **opts).compile()
tauface_kernel = ps.create_staggered_kernel(ob.tauface(), **opts).compile()
continuity_kernel = ps.create_kernel(ob.continuity(), **opts).compile()
force_kernel = ps.create_kernel(ob.force(), **opts).compile()
# ## Set up the simulation
init = macroscopic_values_setter(collision.method, velocity=(0,) * dh.dim,
pdfs=src.center_vector, density=ρ.center)
init_kernel = ps.create_kernel(init, ghost_layers=0).compile()
# no-slip for the fluid, no-flux for the stress
noslip = NoSlip()
noflux = Flux(fv_stencil)
nostressdiff = Flux(fv_stencil, tau.center_vector)
# put some good values into the boundaries so we can take derivatives
noforce = Neumann() # put the same stress into the boundary cells that is in the nearest fluid cell
noflow = Dirichlet((0,) * dh.dim) # put zero velocity into the boundary cells
lbbh.set_boundary(noslip, ps.make_slice[:, :4])
lbbh.set_boundary(noslip, ps.make_slice[:, -4:])
fluxbh.set_boundary(noflux, ps.make_slice[:, :4])
fluxbh.set_boundary(noflux, ps.make_slice[:, -4:])
ubh.set_boundary(noflow, ps.make_slice[:, :4])
ubh.set_boundary(noflow, ps.make_slice[:, -4:])
taufacebh.set_boundary(nostressdiff, ps.make_slice[:, :4])
taufacebh.set_boundary(nostressdiff, ps.make_slice[:, -4:])
for bh in lbbh, fluxbh, ubh, taufacebh:
assert len(bh._boundary_object_to_boundary_info) == 1, "Restart kernel to clear boundaries"
def init():
dh.fill(ρ.name, np.nan, ghost_layers=True, inner_ghost_layers=True)
dh.fill(ρ.name, 1)
dh.fill(u.name, np.nan, ghost_layers=True, inner_ghost_layers=True)
dh.fill(u.name, 0)
dh.fill(tau.name, np.nan, ghost_layers=True, inner_ghost_layers=True)
dh.fill(tau.name, 0)
dh.fill(tauflux.name, np.nan, ghost_layers=True, inner_ghost_layers=True)
dh.fill(tauface.name, np.nan, ghost_layers=True, inner_ghost_layers=True)
dh.fill(F.name, np.nan, ghost_layers=True, inner_ghost_layers=True)
dh.fill(F.name, 0) # needed for LB initialization
sync_tau() # force calculation inside the initialization needs neighbor taus
dh.run_kernel(init_kernel)
dh.fill(F.name, np.nan)
sync_pdfs = dh.synchronization_function([src.name]) # needed before stream, but after collision
sync_u = dh.synchronization_function([u.name]) # needed before continuity, but after stream
sync_tau = dh.synchronization_function([tau.name]) # needed before flux and tauface, but after continuity
def time_loop(steps, lambda_p_val, eta_p_val):
dh.all_to_gpu()
vmid = np.empty((2, steps // 10 + 1))
sync_tau()
sync_u()
ubh()
i = -1
for i in range(steps):
dh.run_kernel(flux_kernel)
fluxbh() # zero the fluxes into/out of boundaries
dh.run_kernel(continuity_kernel, **{lambda_p.name: lambda_p_val, eta_p.name: eta_p_val})
sync_tau()
dh.run_kernel(tauface_kernel) # needed for force
taufacebh()
dh.run_kernel(force_kernel)
dh.run_kernel(collision_kernel, **{eta_p.name: eta_p_val})
sync_pdfs()
lbbh() # bounce-back populations into boundaries
dh.run_kernel(stream_kernel)
sync_u()
ubh() # need neighboring us for flux and continuity
dh.swap(src.name, dst.name)
if i % 10 == 0:
if u.name in dh.gpu_arrays:
dh.to_cpu(u.name)
uu = dh.gather_array(u.name)
uu = uu[L[0] // 2 - 1:L[0] // 2 + 1, L[1] // 2 - 1:L[1] // 2 + 1, 0].mean()
if np.isnan(uu):
raise Exception(f"NaN encountered after {i} steps")
vmid[:, i // 10] = [i, uu]
sync_u()
dh.all_to_cpu()
return vmid[:, :i // 10 + 1]
# ## Analytical solution
#
# comes from Waters and King, Unsteady flow of an elastico-viscous liquid, Rheologica Acta 9, 345–355 (1970).
def N(n):
return (2 * n - 1) * np.pi
def Alpha_n(N, El, eta_p):
return 1 + (1 - eta_p) * El * N * N / 4
def Beta_n(alpha_n, N, El):
return np.sqrt(np.abs(alpha_n * alpha_n - El * N * N))
def Gamma_n(N, El, eta_p):
return 1 - (1 + eta_p) * El * N * N / 4
def G(alpha_n, beta_n, gamma_n, flag, T):
if (flag):
return ((1.0 - gamma_n / beta_n) * np.exp(-(alpha_n + beta_n) * T / 2) +
(1.0 + gamma_n / beta_n) * np.exp((beta_n - alpha_n) * T / 2))
else:
return 2 * np.exp(-alpha_n * T / 2) * (np.cos(beta_n * T / 2) + (gamma_n / beta_n) * np.sin(beta_n * T / 2))
def W(T, El, eta_p):
W_ = 1.5
for n in range(1, 1000):
N_ = N(n)
alpha_n = Alpha_n(N_, El, eta_p)
if alpha_n * alpha_n - El * N_ * N_ < 0:
flag_ = False
else:
flag_ = True
beta_n = Beta_n(alpha_n, N_, El)
gamma_n = Gamma_n(N_, El, eta_p)
G_ = G(alpha_n, beta_n, gamma_n, flag_, T)
W_ -= 24 * (np.sin(N_ / 2) / (N_ * N_ * N_)) * G_
return W_
# ## Run the simulation
lambda_p_val = 3000
eta_p_val = 0.9
init()
vmid = time_loop(lambda_p_val * 4, lambda_p_val, eta_p_val)
actual_width = sum(dh.gather_array(lbbh.flag_array_name)[L[0] // 2, :] == 1)
uref = float(f_pre * actual_width ** 2 / (8 * (eta + eta_p)))
Wi = lambda_p_val * uref / (actual_width / 2)
Re = uref * (actual_width / 2) / (eta + eta_p)
El = float(Wi / Re)
pref = 1 / W(vmid[0, -1] / lambda_p_val, El, eta_p_val)
El_measured, pref_measured = scipy.optimize.curve_fit(lambda a, b, c: W(a, b, eta_p_val) * c,
vmid[0, :] / lambda_p_val, vmid[1, :] / vmid[1, -1],
p0=(El, pref))[0]
measured_width = np.sqrt(4 * lambda_p_val * float(eta + eta_p) / El_measured)
print(f"El={El}, El_measured={El_measured}")
print(f"L={actual_width}, L_measured={measured_width}")
assert abs(measured_width - actual_width) < 1, "effective channel width differs significantly from defined width"
an = W(vmid[0, :] / lambda_p_val, El, eta_p_val) * pref
an_measured = W(vmid[0, :] / lambda_p_val, El_measured, eta_p_val) * pref_measured
diff = abs(vmid[1, :] / vmid[1, -1] - an_measured) / an_measured
assert diff[lambda_p_val // 5:].max() < 0.03, "maximum velocity deviation is too large"
# from pystencils import plot as plt
#
# plt.xlabel("$t$")
# plt.ylabel(r"$u_{max}/u_{max}^{Newtonian}$")
# plt.plot(vmid[0,:], vmid[1,:]/vmid[1,-1] if vmid[1,-1] != 0 else 0, label='FVM')
# plt.plot(vmid[0,:], np.ones_like(vmid[0,:]), 'k--', label='Newtonian')
#
# plt.plot(vmid[0,:], an, label="analytic")
# plt.plot(vmid[0,:], an_measured, label="analytic, fit width")
# plt.legend()
#
# if eta_p_val == 0.1:
# plt.ylim(0.9, 1.15)
# elif lambda_p_val == 9000:
# plt.ylim(0.8, 1.5)
# elif eta_p_val == 0.3:
# plt.ylim(0.8, 1.4)
# plt.show()