本文整理汇总了Python中mbwind.System.setup方法的典型用法代码示例。如果您正苦于以下问题:Python System.setup方法的具体用法?Python System.setup怎么用?Python System.setup使用的例子?那么恭喜您, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类mbwind.System的用法示例。
在下文中一共展示了System.setup方法的15个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的Python代码示例。
示例1: test_solve_reactions
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_solve_reactions(self):
# Check it calls the Element method in the right order: down
# the tree from leaves to base. It must also reset reactions.
s = System()
c0 = RigidConnection('c0')
c1 = RigidConnection('c1')
c2 = RigidConnection('c2')
b1 = RigidBody('b1', 1)
b2 = RigidBody('b2', 1)
s.add_leaf(c0)
c0.add_leaf(c1)
c0.add_leaf(c2)
c1.add_leaf(b1)
c2.add_leaf(b2)
s.setup()
# Check elements' iter_reactions() are called
def mock_iter_reactions(element):
calls.append(element)
calls = []
import types
for el in s.elements.values():
el.iter_reactions = types.MethodType(mock_iter_reactions, el)
# Test
s.joint_reactions[:] = 3
s.solve_reactions()
self.assertEqual(calls, [b2, c2, b1, c1, c0])
assert_aae(s.joint_reactions, 0)示例2: test_solve_accelerations_coupling
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_solve_accelerations_coupling(self):
# Further to test above, check that coupling between prescribed
# accelerations and other dofs is correct. For example, if there
# is a rigid body vertically offset from the joint, then a
# prescribed horizontal acceleration should cause an angular
# acceleration as well as the translational acceleration.
s = System()
j = FreeJoint('joint')
c = RigidConnection('conn', [0, 0, 1.7])
b = RigidBody('body', mass=23.54, inertia=74.1 * np.eye(3))
s.add_leaf(j)
j.add_leaf(c)
c.add_leaf(b)
s.setup()
# Prescribe horizontal acceleration, solve other accelerations
s.prescribe(j, 2.3, part=[0]) # x acceleration
s.update_kinematics() # update system to show prescribed acc
s.solve_accelerations() # solve free accelerations
s.update_kinematics() # update system to show solution
# Ground shouldn't move
assert_aae(j.ap, 0)
# Need angular acceleration = (m a_x L) / I0
I0 = 74.1 + (23.54 * 1.7**2)
expected_angular_acc = -(23.54 * 2.3 * 1.7) / I0
assert_aae(j.ad, [2.3, 0, 0, 0, expected_angular_acc, 0])
assert_aae(j.astrain, j.ad) # not always true, but works for FreeJoint示例3: test_adding_elements
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_adding_elements(self):
conn = RigidConnection('conn')
body = RigidBody('body', mass=1.235)
s = System()
s.add_leaf(conn)
conn.add_leaf(body)
s.setup()
# Should have dict of elements
self.assertEqual(s.elements, {'conn': conn, 'body': body})
# Number of states:
# 6 ground
# + 6 constraints on conn
# + 6 <node-0> between conn and body
# ---
# 18
self.assertEqual(s.lhs.shape, (18, 18))
for vec in (s.rhs, s.qd, s.qdd):
self.assertEqual(len(vec), 18)
# Check there are no dofs
self.assertEqual(len(s.q.dofs), 0)
self.assertEqual(len(s.qd.dofs), 0)
self.assertEqual(len(s.qdd.dofs), 0)示例4: test_inertia_when_offset_axially
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_inertia_when_offset_axially(self):
density = 230.4
length = 20.0
offset = 5.0
element = _mock_rigid_uniform_beam(density, length)
conn = RigidConnection('offset', offset=[offset, 0, 0])
joint = FreeJoint('joint')
system = System()
system.add_leaf(joint)
joint.add_leaf(conn)
conn.add_leaf(element)
system.setup()
# Calculate reduced system to get rigid body matrices
rsys = ReducedSystem(system)
# Expected values: rod along x axis
m = density * length
Iy = m * (length**2 / 12 + (length/2 + offset)**2)
expected_mass = m * eye(3)
expected_inertia = diag([0, Iy, Iy])
expected_offdiag = zeros((3, 3))
# Y accel -> positive moment about Z
# Z accel -> negative moment about Y
expected_offdiag[2, 1] = +m * (length/2 + offset)
expected_offdiag[1, 2] = -m * (length/2 + offset)
assert_aae(rsys.M[:3, :3], expected_mass)
assert_aae(rsys.M[3:, 3:], expected_inertia)
assert_aae(rsys.M[3:, :3], expected_offdiag)
assert_aae(rsys.M[:3, 3:], expected_offdiag.T)示例5: test_solve_accelerations
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_solve_accelerations(self):
# solve_accelerations() should find:
# (a) response of system to forces (here, gravity)
# (b) include any prescribed accelerations in qdd vector
g = 9.81
s = System(gravity=g)
j = FreeJoint('joint')
b = RigidBody('body', mass=23.54, inertia=52.1 * np.eye(3))
s.add_leaf(j)
j.add_leaf(b)
s.setup()
# Prescribe horizontal acceleration. Vertical acceleration
# should result from gravity.
s.prescribe(j, 2.3, part=[0]) # x acceleration
# Initially accelerations are zero
assert_aae(j.ap, 0)
assert_aae(j.ad, 0)
assert_aae(j.astrain, 0)
# Solve accelerations & check
s.solve_accelerations()
s.update_kinematics()
assert_aae(j.ap, 0) # ground
assert_aae(j.ad, [2.3, 0, -g, 0, 0, 0])
assert_aae(j.astrain, j.ad) # not always true, but works for FreeJoint示例6: test_three_rigid_elements_as_disc_have_ends_in_right_place
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_three_rigid_elements_as_disc_have_ends_in_right_place(self):
length = 20.0
offset = 5.0
# Make 3 elements spaced by 120 deg about z axis
system = System()
elements = []
for i in range(3):
rotmat = rotations(('z', i * 2*pi/3))
offset_vector = dot(rotmat, [offset, 0, 0])
conn = RigidConnection('offset%d' % i, offset_vector, rotmat)
element = RigidConnection('element%d' % i, [length, 0, 0])
elements.append(element)
system.add_leaf(conn)
conn.add_leaf(element)
system.setup()
r = offset
R = offset + length
assert_aae(elements[0].rp, [r, 0, 0])
assert_aae(elements[1].rp, [-r/2, r*sqrt(3)/2, 0])
assert_aae(elements[2].rp, [-r/2, -r*sqrt(3)/2, 0])
assert_aae(elements[0].rd, [R, 0, 0])
assert_aae(elements[1].rd, [-R/2, R*sqrt(3)/2, 0])
assert_aae(elements[2].rd, [-R/2, -R*sqrt(3)/2, 0])示例7: test_prescribe_free
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_prescribe_free(self):
s = System()
j = FreeJoint('joint')
s.add_leaf(j)
s.setup()
s.time = 3.54
# Initially all 6 joint motions are free
self.assertEqual(len(s.q.dofs), 6)
# Prescribing joint to be fixed results in no dofs
s.prescribe(j)
self.assertEqual(len(s.q.dofs), 0)
# Freeing joint results in 6 dofs again
s.free(j)
self.assertEqual(len(s.q.dofs), 6)
# Prescribing 2 of joint motions leaves 4 dofs
s.prescribe(j, lambda t: t, [0, 2])
self.assertEqual(len(s.q.dofs), 4)
# Prescribing another joint motions leaves 3 dofs
s.prescribe(j, 2.0, part=3)
self.assertEqual(len(s.q.dofs), 3)
# Check accelerations are applied to qdd
assert_aae(s.qdd[j.istrain], 0)
s.apply_prescribed_accelerations()
assert_aae(s.qdd[j.istrain], [3.54, 0, 3.54, 2.0, 0, 0])
# Freeing joint results in 6 dofs again
s.free(j)
self.assertEqual(len(s.q.dofs), 6)示例8: test_simple_prescribed_integration
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_simple_prescribed_integration(self):
s = System()
h = Hinge('hinge', [0, 1, 0])
s.add_leaf(h)
s.setup()
s.prescribe(h)
w = h.vstrain[0] = 0.97 # rad/s
integ = Integrator(s)
t, y = integ.integrate(9.0, 0.1)
# Check time vector and shape of result
assert_array_equal(t, np.arange(0, 9.0, 0.1))
self.assertEqual(len(y), 1)
self.assertEqual(y[0].shape, (len(t), 1))
# Result should be y = wt, but wrapped to [0, 2pi)
assert_aae(y[0][:, 0], (w * t) % (2 * np.pi))
# Check asking for velocity and acceleration works
h.xstrain[0] = s.time = 0.0 # reset
integ = Integrator(s, ('pos', 'vel', 'acc'))
t, y = integ.integrate(1.0, 0.1)
assert_array_equal(t, np.arange(0, 1.0, 0.1))
self.assertEqual(len(y), 3)
for yy in y:
self.assertEqual(yy.shape, (len(t), 1))
assert_aae(y[0][:, 0], w * t)
assert_aae(y[1][:, 0], w)
assert_aae(y[2][:, 0], 0)示例9: test_1dof_nonlinear_system
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_1dof_nonlinear_system(self):
s = System()
j = PrismaticJoint('joint', [0, 0, 1])
k = 0.45 # quadratic stiffness coefficient
j.internal_force = lambda el, t: -k * el.xstrain[0]**2
b = RigidBody('body', 10)
s.add_leaf(j)
j.add_leaf(b)
s.setup()
# Linearise around z0 = 0: stiffness should be zero
linsys = LinearisedSystem.from_system(s, z0=0)
assert_aae(linsys.M, [[10.0]])
assert_aae(linsys.C, [[0.0]])
assert_aae(linsys.K, [[0.0]])
# Linearise about z0 = 2: stiffness should be 2kx
linsys = LinearisedSystem.from_system(s, z0=[2])
assert_aae(linsys.M, [[10.0]])
assert_aae(linsys.C, [[0.0]])
assert_aae(linsys.K, [[2 * k * 2]])
# Test setting z0 in another way
linsys = LinearisedSystem.from_system(s, z0={'joint': [4.2]})
assert_aae(linsys.M, [[10.0]])
assert_aae(linsys.C, [[0.0]])
assert_aae(linsys.K, [[2 * k * 4.2]])示例10: test_nonzero_prescribed_acceleration
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_nonzero_prescribed_acceleration(self):
# Test reduction where a prescribed acceleration is non-zero:
# two sliders in series, with a mass on the end. If the second
# slider's acceleration is prescribed, the first slider's DOF
# sees an inertial force corresponding to the acceleration of
# the mass.
mass = 36.2
s = System()
s1 = PrismaticJoint('slider1', [1, 0, 0])
s2 = PrismaticJoint('slider2', [1, 0, 0])
b = RigidBody('body', mass)
s.add_leaf(s1)
s1.add_leaf(s2)
s2.add_leaf(b)
s.setup()
s.prescribe(s2, acc=0)
# With hinge angle = 0, no generalised inertial force
rsys = ReducedSystem(s)
assert_aae(rsys.M, mass)
assert_aae(rsys.Q, 0)
# With hinge angle = 90deg, do see generalised inertial force
s.prescribe(s2, acc=2.3)
rsys = ReducedSystem(s)
assert_aae(rsys.M, mass)
assert_aae(rsys.Q, -mass * 2.3)示例11: test_single_rigid_body
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_single_rigid_body(self):
mass = 36.2
inertia = np.diag([75.4, 653, 234])
s = System()
j = FreeJoint('joint')
b = RigidBody('body', mass, inertia)
s.add_leaf(j)
j.add_leaf(b)
s.setup()
# Calculate reduced system to get rigid body matrices
rsys = ReducedSystem(s)
self.assertEqual(rsys.M.shape, (6, 6))
self.assertEqual(rsys.Q.shape, (6,))
assert_aae(rsys.M[:3, :3], mass * np.eye(3))
assert_aae(rsys.M[3:, 3:], inertia)
assert_aae(rsys.M[3:, :3], 0)
assert_aae(rsys.M[:3, 3:], 0)
assert_aae(rsys.Q, 0)
# Now if some freedoms are prescribed, don't appear in reduced system
s.prescribe(j, part=[1, 2, 3, 4, 5]) # only x-translation is free now
rsys = ReducedSystem(s)
self.assertEqual(rsys.M.shape, (1, 1))
self.assertEqual(rsys.Q.shape, (1,))
assert_aae(rsys.M[0, 0], mass)
assert_aae(rsys.Q, 0)示例12: test_dof_index
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_dof_index(self):
s = System()
j1 = FreeJoint('j1')
j2 = FreeJoint('j2')
s.add_leaf(j1)
j1.add_leaf(j2)
s.setup()
# Prescribe some of the strains:
# _____j1____ _____j2____
# Strain: 0 1 2 3 4 5 0 1 2 3 4 5
# Prescr: * * *
# Dofs: 0 1 2 3 4 5 6 7 8
s.prescribe(j1, 0, part=[1, 4])
s.prescribe(j2, 0, part=[3])
self.assertEqual(s.dof_index('j1', 0), 0)
self.assertEqual(s.dof_index('j1', 2), 1)
self.assertEqual(s.dof_index('j1', 5), 3)
self.assertEqual(s.dof_index('j2', 5), 8)
# Strain index out of range should give IndexError
with self.assertRaises(IndexError):
s.dof_index('j1', 6)
# Asking for index of prescribed strain should give ValueError
with self.assertRaises(ValueError):
s.dof_index('j1', 1)示例13: test_call
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_call(self):
s = System()
c = RigidConnection('conn', [1, 0, 0])
h = Hinge('hinge', [0, 1, 0])
b = RigidBody('body', 1)
s.add_leaf(h)
h.add_leaf(c)
c.add_leaf(b)
s.setup()
# Set hinge angle
h.xstrain[0] = 0.82
h.vstrain[0] = 1.2
h.astrain[0] = -0.3
s.update_kinematics()
s.solve_reactions()
# Test load outputs
out = LoadOutput('node-1')
assert_array_equal(out(s), s.joint_reactions['node-1'])
out = LoadOutput('node-1', local=True)
F = s.joint_reactions['node-1']
assert_array_equal(out(s), np.r_[np.dot(b.Rp.T, F[:3]),
np.dot(b.Rp.T, F[3:])])示例14: test_rigid_body_with_no_dofs
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_rigid_body_with_no_dofs(self):
s = System()
b = RigidBody('body', 23.7)
s.add_leaf(b)
s.setup()
# Calculate reduced system to get rigid body matrices
rsys = ReducedSystem(s)
self.assertEqual(rsys.M.shape, (0, 0))
self.assertEqual(rsys.Q.shape, (0,))示例15: test_print_functions
# 需要导入模块: from mbwind import System [as 别名]
# 或者: from mbwind.System import setup [as 别名]
def test_print_functions(self):
# Not very good tests, but at least check they run without errors
joint = FreeJoint('joint')
body = RigidBody('body', mass=1.235)
s = System()
s.add_leaf(joint)
joint.add_leaf(body)
s.setup()
s.print_states()
s.print_info()