def setUp(self):
self.strength = 35.0
self.H = history.History()
self.H.add_scalar("strength")
self.H.set_scalar("strength", self.strength)
self.H.add_scalar("whatever")
self.H.set_scalar("whatever", 0.5)
self.tau0 = 10.0
self.tau_sat = 50.0
self.b = 2.5
self.strengthmodel = slipharden.VoceSlipHardening(
self.tau_sat, self.b, self.tau0)
self.g0 = 1.0
self.n = 3.0
self.slipmodel = sliprules.PowerLawSlipRule(self.strengthmodel,
self.g0, self.n)
self.imodel = inelasticity.AsaroInelasticity(self.slipmodel)
self.L = crystallography.CubicLattice(1.0)
self.L.add_slip_system([1, 1, 0], [1, 1, 1])
self.Q = rotations.Orientation(35.0, 17.0, 14.0, angle_type="degrees")
self.S = tensors.Symmetric(
np.array([[100.0, -25.0, 10.0], [-25.0, -17.0, 15.0],
[10.0, 15.0, 35.0]]))
self.T = 300.0
self.mu = 29000.0
self.E = 120000.0
self.nu = 0.3
self.emodel = elasticity.CubicLinearElasticModel(
self.E, self.nu, self.mu, "moduli")
self.dn = np.array([[4.1, 2.8, -1.2], [3.1, 7.1, 0.2], [4, 2, 3]])
self.dn = 0.5 * (self.dn + self.dn.T)
self.d = tensors.Symmetric(self.dn)
self.wn = np.array([[-9.36416517, 2.95527444, 8.70983194],
[-1.54693052, 8.7905658, -5.10895168],
[-8.52740468, -0.7741642, 2.89544992]])
self.wn = 0.5 * (self.wn - self.wn.T)
self.w = tensors.Skew(self.wn)
self.dmodel = crystaldamage.NilDamageModel()
self.model = kinematics.DamagedStandardKinematicModel(
self.emodel, self.imodel, self.dmodel)
self.fspin = self.model.spin(self.S, self.d, self.w, self.Q, self.H,
self.L, self.T, history.History())
self.fixed = self.model.decouple(self.S, self.d, self.w, self.Q,
self.H, self.L, self.T,
history.History())
def test_normal_usecase(self):
"""
Actually check that the stiffness in the appropriate direction resolves
to zero
"""
strain = tensors.Symmetric(np.array([[1, 1, 1], [1, 1, 1], [1, 1, 1]]))
emodel = elasticity.CubicLinearElasticModel(100000.0, 0.3, 60000.0,
"moduli")
C = emodel.C_tensor(0)
n = tensors.Vector([1.0, -1, 1]).normalize()
P = projections.normal_projection_ss(n)
PP = tensors.SymSymR4.id() - P
PC = PP.dot(C)
stress = PC.dot(strain).to_full()
val = stress.dot(n).dot(n)
self.assertAlmostEqual(val, 0)
# Some random orthogonal direction
s = n.cross(tensors.Vector([1, 0.0, 0])).normalize()
val = stress.dot(s).dot(s)
val2 = C.dot(strain).dot(s).dot(s)
self.assertAlmostEqual(val, val2)
def setUp(self):
self.mu = 29000.0
self.E = 120000.0
self.nu = 0.3
self.T = 325.0
self.Q = rotations.Orientation(31.0, 59.0, 80.0, angle_type = "degrees",
convention = "bunge")
self.Q_cube = rotations.Orientation(90.0, 0.0, 0.0, angle_type = "degrees",
convention = "bunge")
self.model = elasticity.CubicLinearElasticModel(self.E,
self.nu, self.mu, "moduli")
self.v1 = tensors.Vector(np.array([1.0,0.0,0]))
self.v2 = tensors.Vector(np.array([0.0,1.0,0]))
def setUp(self):
self.N = 10
self.tau0 = 10.0
self.tau_sat = 50.0
self.b = 2.5
self.strengthmodel = slipharden.VoceSlipHardening(self.tau_sat, self.b, self.tau0)
self.g0 = 1.0
self.n = 3.0
self.slipmodel = sliprules.PowerLawSlipRule(self.strengthmodel, self.g0, self.n)
self.imodel = inelasticity.AsaroInelasticity(self.slipmodel)
self.L = crystallography.CubicLattice(1.0)
self.L.add_slip_system([1,1,0],[1,1,1])
self.Q = rotations.Orientation(35.0,17.0,14.0, angle_type = "degrees")
self.mu = 29000.0
self.E = 120000.0
self.nu = 0.3
self.emodel = elasticity.CubicLinearElasticModel(self.E,
self.nu, self.mu, "moduli")
self.kmodel = kinematics.StandardKinematicModel(self.emodel, self.imodel)
self.model = singlecrystal.SingleCrystalModel(self.kmodel, self.L,
miter = 120)
self.orientations = rotations.random_orientations(self.N)
self.D = np.array([0.01,-0.002,-0.003,0.012,-0.04,0.01])
self.W = np.array([0.02,-0.02,0.03])
self.T = 300.0
self.dt = 2.0
def test_shear_usecase(self):
"""
Actually check that the stiffness in the shear directions resolves to zero
"""
strain = tensors.Symmetric(np.array([[1, 1, 1], [1, 1, 1], [1, 1, 1]]))
emodel = elasticity.CubicLinearElasticModel(100000.0, 0.3, 60000.0,
"moduli")
C = emodel.C_tensor(0)
n = tensors.Vector([1.0, -1, 1]).normalize()
s = n.cross(tensors.Vector([1, 0, 0])).normalize()
t = n.cross(s)
P = projections.shear_projection_ss(n)
PP = tensors.SymSymR4.id() - P
PC = PP.dot(C)
stress = PC.dot(strain).to_full()
v1 = stress.dot(n).dot(s)
self.assertAlmostEqual(v1, 0)
v2 = stress.dot(n).dot(t)
self.assertAlmostEqual(v2, 0)
extra = (s + t).normalize()
v3 = stress.dot(n).dot(extra)
self.assertAlmostEqual(v3, 0)
# IDK, i guess check normal on a different plane
vn1 = stress.dot(n).dot(n)
vn2 = C.dot(strain).dot(n).dot(n)
self.assertAlmostEqual(vn1, vn2)
# IDK, i guess check shear on a different plane
vn1 = stress.dot(s).dot(t)
vn2 = C.dot(strain).dot(s).dot(t)
self.assertAlmostEqual(vn1, vn2)
def setUp(self):
self.tau0 = 10.0
self.tau_sat = 50.0
self.b = 2.5
self.strengthmodel = slipharden.VoceSlipHardening(
self.tau_sat, self.b, self.tau0)
self.g0 = 1.0
self.n = 3.0
self.slipmodel = sliprules.PowerLawSlipRule(self.strengthmodel,
self.g0, self.n)
self.imodel = inelasticity.AsaroInelasticity(self.slipmodel)
self.L = crystallography.CubicLattice(1.0)
self.L.add_slip_system([1, 1, 0], [1, 1, 1])
self.Q = rotations.Orientation(35.0, 17.0, 14.0, angle_type="degrees")
self.mu = 29000.0
self.E = 120000.0
self.nu = 0.3
self.emodel = elasticity.CubicLinearElasticModel(
self.E, self.nu, self.mu, "moduli")
self.kmodel = kinematics.StandardKinematicModel(
self.emodel, self.imodel)
self.model = singlecrystal.SingleCrystalModel(self.kmodel,
self.L,
initial_rotation=self.Q)
self.model_no_rot = singlecrystal.SingleCrystalModel(
self.kmodel,
self.L,
initial_rotation=self.Q,
update_rotation=False,
verbose=False)
self.T = 300.0
self.stress_n = np.array([120.0, -60.0, 170.0, 35.0, 80.0, -90.0])
self.stress_np1 = np.array([15.0, -40.0, 120.0, 70.0, -10.0, -50.0])
self.d = np.array([0.1, -0.2, 0.25, 0.11, -0.05, 0.075])
self.w = np.array([0.1, 0.2, -0.2])
self.strength_n = 25.0
self.strength_np1 = 30.0
self.S_np1 = tensors.Symmetric(common.usym(self.stress_np1))
self.S_n = tensors.Symmetric(common.usym(self.stress_n))
self.D = tensors.Symmetric(common.usym(self.d))
self.W = tensors.Skew(common.uskew(self.w))
self.strength_n = 25.0
self.strength_np1 = 30.0
self.H_n = history.History()
self.H_n.add_scalar("strength")
self.H_n.set_scalar("strength", self.strength_n)
self.H_np1 = history.History()
self.H_np1.add_scalar("strength")
self.H_np1.set_scalar("strength", self.strength_np1)
self.dt = 2.0
self.fixed = self.kmodel.decouple(self.S_n, self.D, self.W, self.Q,
self.H_n, self.L, self.T,
history.History())
self.ts = singlecrystal.SCTrialState(self.D, self.W, self.S_n,
self.H_n, self.Q, self.L, self.T,
self.dt, self.fixed)
self.x = np.zeros((self.model.nparams, ))
self.x[:6] = self.stress_np1
self.x[6] = self.strength_np1
self.Ddir = np.array([0.01, -0.005, -0.003, 0.01, 0.02, -0.003]) * 2
self.Wdir = np.array([0.02, -0.03, 0.01]) * 2
self.nsteps = 10
t0 = 100.0
b = 10.0
sat = 50
g0 = 1.0e-4
n = 6.0
mu = 29000.0
E = 120000.0
nu = 0.3
c = 40
beta = 3.0
emodel = elasticity.CubicLinearElasticModel(E, nu, mu, "moduli")
strengthmodel = slipharden.VoceSlipHardening(sat, b, t0)
slipmodel = sliprules.PowerLawSlipRule(strengthmodel, g0, n)
imodel = inelasticity.AsaroInelasticity(slipmodel)
base_kin = kinematics.StandardKinematicModel(emodel, imodel)
base_cp_model = singlecrystal.SingleCrystalModel(base_kin, lattice)
base_model = polycrystal.TaylorModel(base_cp_model,
orientations,
nthreads=nthreads)
base_kin = kinematics.StandardKinematicModel(emodel, imodel)
base_cp_model = singlecrystal.SingleCrystalModel(base_kin, lattice)
def setUp(self):
self.L = crystallography.CubicLattice(1.0)
self.L.add_slip_system([1, 1, 0], [1, 1, 1])
self.nslip = self.L.ntotal
self.strength = 35.0
self.c = 10.0
self.beta = 2.0
self.H = history.History()
for i in range(12):
self.H.add_scalar("strength" + str(i))
self.H.set_scalar("strength" + str(i), self.strength)
for j in range(4):
self.H.add_scalar("slip_damage_" + str(j))
self.H.set_scalar("slip_damage_" + str(j), self.c * 0.4)
self.static = 20.0
self.s0 = [self.static] * self.nslip
self.k = 1000.0
self.sat = 40.0
self.m = 1.5
self.strengthmodel = slipharden.VocePerSystemHardening(
self.s0, [self.k] * self.nslip, [self.sat] * self.nslip,
[self.m] * self.nslip)
self.g0 = 1.0
self.n = 3.0
self.slipmodel = sliprules.PowerLawSlipRule(self.strengthmodel,
self.g0, self.n)
self.imodel = inelasticity.AsaroInelasticity(self.slipmodel)
self.Q = rotations.Orientation(35.0, 17.0, 14.0, angle_type="degrees")
self.S = tensors.Symmetric(
np.array([[100.0, -25.0, 10.0], [-25.0, -17.0, 15.0],
[10.0, 15.0, 35.0]]))
self.T = 300.0
self.mu = 29000.0
self.E = 120000.0
self.nu = 0.3
self.emodel = elasticity.CubicLinearElasticModel(
self.E, self.nu, self.mu, "moduli")
self.dn = np.array([[4.1, 2.8, -1.2], [3.1, 7.1, 0.2], [4, 2, 3]])
self.dn = 0.5 * (self.dn + self.dn.T)
self.d = tensors.Symmetric(self.dn)
self.wn = np.array([[-9.36416517, 2.95527444, 8.70983194],
[-1.54693052, 8.7905658, -5.10895168],
[-8.52740468, -0.7741642, 2.89544992]])
self.wn = 0.5 * (self.wn - self.wn.T)
self.w = tensors.Skew(self.wn)
self.dmodel = crystaldamage.WorkPlaneDamage()
self.nfunc = crystaldamage.SigmoidTransformation(self.c, self.beta)
self.sfunc = crystaldamage.SigmoidTransformation(self.c, self.beta)
self.dmodel = crystaldamage.PlanarDamageModel(self.dmodel, self.nfunc,
self.sfunc, self.L)
self.model = kinematics.DamagedStandardKinematicModel(
self.emodel, self.imodel, self.dmodel)
self.fspin = self.model.spin(self.S, self.d, self.w, self.Q, self.H,
self.L, self.T, history.History())
self.fixed = self.model.decouple(self.S, self.d, self.w, self.Q,
self.H, self.L, self.T,
history.History())
