fluidic_traction_density_env_2d.py
import numpy as np
from py_diff_stokes_flow.env.env_base import EnvBase
from py_diff_stokes_flow.common.common import ndarray
from matplotlib import collections as mc
import matplotlib.pyplot as plt
class FluidicTractionDensityEnv2d(EnvBase):
def __init__(self, seed, folder):
np.random.seed(seed)
cell_nums = (32, 24)
E = 100
nu = 0.499
vol_tol = 1e-3
edge_sample_num = 2
EnvBase.__init__(self, cell_nums, E, nu, vol_tol, edge_sample_num, folder)
# Initialize the parametric shapes.
self._parametric_shape_info = [ ('bezier', 8), ('bezier', 8) ]
# Initialize the node conditions.
self._node_boundary_info = []
inlet_velocity = 1
inlet_range = ndarray([0.125, 0.875])
inlet_lb, inlet_ub = inlet_range * cell_nums[1]
for j in range(cell_nums[1] + 1):
if inlet_lb < j < inlet_ub:
self._node_boundary_info.append(((0, j, 0), inlet_velocity))
self._node_boundary_info.append(((0, j, 1), 0))
# Initialize the interface.
self._interface_boundary_type = 'free-slip'
# Other data members.
self._inlet_velocity = inlet_velocity
self._outlet_velocity = 3 * inlet_velocity
self._inlet_range = inlet_range
# Lame parameters.
self._E = E
self._nu = nu
la = E * nu / (1 + nu) / (1 - 2 * nu)
mu = E / 2 / (1 + nu)
self._la = la
self._mu = mu
def _variables_to_shape_params(self, x):
x = ndarray(x).copy().ravel()
assert x.size == 5
cx, cy = self._cell_nums
# Convert x to the shape parameters.
lower = ndarray([
[1, x[4]],
x[2:4],
x[:2],
[0, self._inlet_range[0]],
])
lower[:, 0] *= cx
lower[:, 1] *= cy
upper = ndarray([
[0, self._inlet_range[1]],
[x[0], 1 - x[1]],
[x[2], 1 - x[3]],
[1, 1 - x[4]],
])
upper[:, 0] *= cx
upper[:, 1] *= cy
params = np.concatenate([lower.ravel(), upper.ravel()])
# Jacobian.
J = np.zeros((params.size, x.size))
J[1, 4] = 1
J[2, 2] = 1
J[3, 3] = 1
J[4, 0] = 1
J[5, 1] = 1
J[10, 0] = 1
J[11, 1] = -1
J[12, 2] = 1
J[13, 3] = -1
J[15, 4] = -1
# Scale it by cx and cy.
J[:, 0] *= cx
J[:, 2] *= cx
J[:, 1] *= cy
J[:, 3] *= cy
J[:, 4] *= cy
return ndarray(params).copy(), ndarray(J).copy()
def _loss_and_grad(self, scene, u):
param_size = self._variables_to_shape_params(self.lower_bound())[0].size
grad_param = ndarray(np.zeros(param_size))
return 0, ndarray(np.zeros(u.shape).ravel()), grad_param
def _render_customized_2d(self, scene, u_field, ax):
nx, ny = self._node_nums
cx, cy = self._cell_nums
lines = []
sample_num = 20
scale = 0.1
for i in range(cx):
for j in range(cy):
# Only visualize hybrid cells.
if not scene.IsMixedCell((i, j)): continue
n = ndarray(scene.GetNormalInMixedCell((i, j)))
d = scene.GetOffsetInMixedCell((i, j))
# n.dot(x) + d >= 0 is the solid area.
n_len = np.linalg.norm(n)
n /= n_len
d /= n_len
assert n[0] != 0 and n[1] != 0
# Determine the boundary inside this cell.
# We have a line: n.dot(x) + d = 0.
# We have a square: [i, i + 1] x [j, j + 1].
# Compute p0 and p1.
# Pick an anchor point first.
# n[0] * x + n[1] * y + d = 0.
q = ndarray([0, -d / n[1]])
d = ndarray([n[1], -n[0]])
# Line equation now becomes q + t * d.
# q + t * d = [i, ?]
tx0 = (0 - q[0]) / d[0]
tx1 = (1 - q[0]) / d[0]
if tx0 > tx1:
tx0, tx1 = tx1, tx0
# Now tx0 <= tx1.
# q + t * d = [?, j]
ty0 = (0 - q[1]) / d[1]
ty1 = (1 - q[1]) / d[1]
if ty0 > ty1:
ty0, ty1 = ty1, ty0
# Now ty0 <= ty1.
t_min = np.max([tx0, ty0])
t_max = np.min([tx1, ty1])
assert t_min <= t_max
p0 = q + t_min * d
p1 = q + t_max * d
dl = np.linalg.norm(p1 - p0)
assert 0 <= np.min(p0) <= np.max(p0) <= 1
assert 0 <= np.min(p1) <= np.max(p1) <= 1
# Collect velocity fields.
u00 = u_field[i, j]
u01 = u_field[i, j + 1]
u10 = u_field[i + 1, j]
u11 = u_field[i + 1, j + 1]
def compute_F(p):
X, Y = p
# x = (1 - X) * (1 - Y) * u00 +
# (1 - X) * Y * u01 +
# X * (1 - Y) * u10 +
# XY * u11.
F = np.zeros((2, 2))
F[:, 0] = -(1 - Y) * u00 - Y * u01 + (1 - Y) * u10 + Y * u11
F[:, 1] = -(1 - X) * u00 + (1 - X) * u01 - X * u10 + X * u11
return F
# Integrate along the edge.
total_traction = 0
for k in range(sample_num):
t = (k + .5) / sample_num
p = (1 - t) * p0 + t * p1
F = compute_F(p)
sigma = self._mu * (F + F.T) + self._la * np.trace(F) * np.eye(2)
# Compute traction.
total_traction += sigma @ -n * dl / sample_num
v_begin = ndarray([i, j]) + (p0 + p1) / 2
v_end = v_begin + scale * total_traction
lines.append((v_begin, v_end))
ax.add_collection(mc.LineCollection(lines, colors='tab:orange', linestyle='-'))
def sample(self):
return ndarray([0.37398444, 0.38338892, 0.5783081 , 0.37403294, 0.37916777])
def lower_bound(self):
return ndarray([0.16, 0.05, 0.49, 0.05, 0.05])
def upper_bound(self):
return ndarray([0.49, 0.49, 0.83, 0.49, 0.49])