def psi_plus_linear_elasticity_model_C(epsilon, lamda, mu):
sqrt_delta = fe.conditional(
fe.gt(fe.tr(epsilon)**2 - 4 * fe.det(epsilon), 0),
fe.sqrt(fe.tr(epsilon)**2 - 4 * fe.det(epsilon)), 0)
eigen_value_1 = (fe.tr(epsilon) + sqrt_delta) / 2
eigen_value_2 = (fe.tr(epsilon) - sqrt_delta) / 2
tr_epsilon_plus = fe.conditional(fe.gt(fe.tr(epsilon), 0.), fe.tr(epsilon),
0.)
eigen_value_1_plus = fe.conditional(fe.gt(eigen_value_1, 0.),
eigen_value_1, 0.)
eigen_value_2_plus = fe.conditional(fe.gt(eigen_value_2, 0.),
eigen_value_2, 0.)
return lamda / 2 * tr_epsilon_plus**2 + mu * (eigen_value_1_plus**2 +
eigen_value_2_plus**2)
def ratio_function_ufl(ratio, map_type):
if map_type == 'linear':
return fe.conditional(
fe.lt(ratio, -1. / 2.), 3. / 2. * ratio + 1. / 2.,
fe.conditional(fe.gt(ratio, 1. / 2.), 3. / 2. * ratio - 1. / 2.,
1. / 2. * ratio))
elif map_type == 'power':
return ratio**(2.)
elif map_type == 'identity':
return ratio
elif map_type == 'smooth':
return fe.conditional(fe.lt(ratio, -1./2.), -6*ratio**3 - 14*ratio**2 - 9*ratio - 2, \
fe.conditional(fe.gt(ratio, 1./2.), -6*ratio**3 + 14*ratio**2 - 9*ratio + 2, 1./2.* ratio))
else:
raise NotImplementedError("To be implemented")
def inverse_map_function_ufl(x, control_points, impact_radii, map_type):
if len(control_points) == 0:
return x
x = fe.variable(x)
df, rho = distance_function_segments_ufl(x, control_points, impact_radii)
grad_x = fe.diff(df, x)
delta_x = fe.conditional(
fe.gt(df, rho), fe.Constant((0., 0.)),
grad_x * (rho * inverse_ratio_function_ufl(df / rho, map_type) - df))
return delta_x + x
def compute_analytical_solutions_fully_broken(self, x):
x1 = x[0]
x2 = x[1]
u1 = fe.Constant(0.)
u2 = fe.conditional(fe.gt(x2, self.height / 2.), self.fix_load,
fe.Constant(0.))
u_exact = fe.as_vector([u1, u2])
distance_field, _ = distance_function_segments_ufl(
x, self.control_points, self.impact_radii)
d_exact = fe.exp(-distance_field / (self.l0))
return u_exact, d_exact
def distance_function_line_segement_ufl(P, A=[-1, 0], B=[1, 0]):
AB = [None, None]
AB[0] = B[0] - A[0]
AB[1] = B[1] - A[1]
BP = [None, None]
BP[0] = P[0] - B[0]
BP[1] = P[1] - B[1]
AP = [None, None]
AP[0] = P[0] - A[0]
AP[1] = P[1] - A[1]
AB_BP = AB[0] * BP[0] + AB[1] * BP[1]
AB_AP = AB[0] * AP[0] + AB[1] * AP[1]
y = P[1] - B[1]
x = P[0] - B[0]
df1 = fe.sqrt(x**2 + y**2)
xi1 = 1
y = P[1] - A[1]
x = P[0] - A[0]
df2 = fe.sqrt(x**2 + y**2)
xi2 = 0
x1 = AB[0]
y1 = AB[1]
x2 = AP[0]
y2 = AP[1]
mod = fe.sqrt(x1**2 + y1**2)
df3 = np.absolute(x1 * y2 - y1 * x2) / mod
xi3 = fe.conditional(fe.gt(x2**2 + y2**2 - df3**2, 0),
fe.sqrt(x2**2 + y2**2 - df3**2) / mod, 0)
df = fe.conditional(fe.gt(AB_BP, 0), df1,
fe.conditional(fe.lt(AB_AP, 0), df2, df3))
xi = fe.conditional(fe.gt(AB_BP, 0), xi1,
fe.conditional(fe.lt(AB_AP, 0), xi2, xi3))
return df, xi
def inverse_ratio_function_ufl(ratio, map_type):
if map_type == 'linear':
return fe.conditional(
fe.lt(ratio, -1. / 4.), 2. / 3. * ratio - 1. / 3.,
fe.conditional(fe.gt(ratio, 1. / 4.), 2. / 3. * ratio + 1. / 3.,
2. * ratio))
elif map_type == 'power':
return ratio**(0.5)
elif map_type == 'identity':
return ratio
else:
raise NotImplementedError("To be implemented")
def update_map(self):
d_clipped = fe.conditional(fe.gt(self.d_new, 0.5), self.d_new, 0.)
d_int_full = fe.assemble(self.d_new * fe.det(self.grad_gamma) * fe.dx)
d_int = fe.assemble(d_clipped * fe.det(self.grad_gamma) * fe.dx)
print("d_int_clipped {}".format(float(d_int)))
print("d_int_full {}".format(float(d_int_full)))
update_flag = False
if d_int - self.d_integrals[-1] > self.d_integral_interval:
update_flag = True
if update_flag and not self.finish_flag:
print('\n')
print(
'================================================================================='
)
print('>> Updating map...')
print(
'================================================================================='
)
new_tip_point = self.identify_crack_tip()
if self.inside_domain(new_tip_point):
if len(self.control_points) > 1:
v1 = self.control_points[-1] - self.control_points[-2]
v2 = new_tip_point - self.control_points[-1]
v1 = v1 / np.linalg.norm(v1)
v2 = v2 / np.linalg.norm(v2)
print("new_tip_point is {}".format(new_tip_point))
print("v1 is {}".format(v1))
print("v2 is {}".format(v2))
print("control points are \n{}".format(
self.control_points))
print("impact_radii are {}".format(self.impact_radii))
assert np.dot(
v1, v2
) > np.sqrt(2) / 2, "Crack propogration angle not good"
self.compute_impact_radii(new_tip_point)
self.interpolate_H()
self.d_integrals.append(d_int)
print(
'================================================================================='
)
else:
self.finish_flag = True
self.update_weak_form = True
else:
print("Do not modify map")
print("d_integrals {}".format(self.d_integrals))
def obj(x):
p = fe.Constant(x)
x_coo = fe.SpatialCoordinate(self.mesh)
control_points = list(self.control_points)
control_points.append(p)
pseudo_radii = np.zeros(len(control_points))
distance_field, _ = distance_function_segments_ufl(
x_coo, control_points, pseudo_radii)
d_artificial = fe.exp(-distance_field / self.l0)
d_clipped = fe.conditional(fe.gt(self.d_new, 0.5), self.d_new, 0.)
L_tape = fe.assemble((d_clipped - d_artificial)**2 *
fe.det(self.grad_gamma) * fe.dx)
# L_tape = fe.assemble((self.d_new - d_artificial)**2 * fe.det(self.grad_gamma) * fe.dx)
L = float(L_tape)
return L
def map_function_ufl(x_hat,
control_points,
impact_radii,
map_type,
boundary_info=None):
if len(control_points) == 0:
return x_hat
x_hat = fe.variable(x_hat)
df, rho = distance_function_segments_ufl(x_hat, control_points,
impact_radii)
grad_x_hat = fe.diff(df, x_hat)
delta_x_hat = fe.conditional(
fe.gt(df, rho), fe.Constant((0., 0.)),
grad_x_hat * (rho * ratio_function_ufl(df / rho, map_type) - df))
if boundary_info is None:
return delta_x_hat + x_hat
else:
last_control_point = control_points[-1]
points, directions, rho_default = boundary_info
mid_point, mid_point1, mid_point2 = points
direct_vec, rotated_vec = directions
aux_control_point1 = last_control_point + rho_default * rotated_vec
aux_control_point2 = last_control_point - rho_default * rotated_vec
w1 = np.linalg.norm(mid_point1 - aux_control_point1)
w2 = np.linalg.norm(mid_point2 - aux_control_point2)
w0 = np.linalg.norm(mid_point - last_control_point)
assert np.absolute(2 * w0 - w1 - w2) < 1e-5
AB = mid_point - last_control_point
AP = x_hat - last_control_point
x1 = AB[0]
y1 = AB[1]
x2 = AP[0]
y2 = AP[1]
mod = fe.sqrt(x1**2 + y1**2)
df_to_direct = (x1 * y2 - y1 * x2) / mod # AB x AP
df_to_rotated = (x1 * x2 + y1 * y2) / mod
k1 = rho_default * (w1 + w2) / (rho_default *
(w1 + w2) + df_to_direct * (w1 - w2))
new_df_to_direct = rho_default * ratio_function_ufl(
df_to_direct / rho_default, map_type)
k2 = rho_default * (w1 + w2) / (rho_default *
(w1 + w2) + new_df_to_direct *
(w1 - w2))
new_df_to_rotated = df_to_rotated * k1 / k2
x = fe.as_vector(last_control_point + direct_vec * new_df_to_rotated +
rotated_vec * new_df_to_direct)
return fe.conditional(
fe.gt(df_to_rotated, 0),
fe.conditional(fe.gt(np.absolute(df_to_direct), rho), x_hat, x),
delta_x_hat + x_hat)
def history(H_old, psi_new, psi_cr):
history_max_tmp = fe.conditional(fe.gt(psi_new - psi_cr, 0),
psi_new - psi_cr, 0)
history_max = fe.conditional(fe.gt(history_max_tmp, H_old),
history_max_tmp, H_old)
return history_max
def d3(grad_u):
norm = fe.sqrt(fe.inner(grad_u, grad_u))
return fe.conditional(fe.gt(norm, 1), 1 - 1 / norm, 1 - (2 - norm))
