Exemplo n.º 1
0
                             n_col=n_col,
                             x_shift=1.8,
                             roca_size=0.1,
                             top=3,
                             rate=0.2,
                             density=density)

    io.add_Newton_impact_friction_nsl('contact', mu=1.0, e=0.01)

run_options = MechanicsHdf5Runner_run_options()
run_options['t0'] = 0
run_options['T'] = T
run_options['h'] = hstep
run_options['theta'] = 1.0

bullet_options = SiconosBulletOptions()
bullet_options.perturbationIterations = 0.
#bullet_options.minimumPointsPerturbationThreshold = 0.

run_options['bullet_options'] = bullet_options
run_options['solver_options'] = options
run_options['constraint_activation_threshold'] = 1e-05

run_options['end_run_iteration_hook'] = dh

run_options['Newton_options'] = sk.SICONOS_TS_LINEAR
run_options['skip_last_update_output'] = True
run_options['skip_reset_lambdas'] = True

#run_options['osns_assembly_type']= sk.REDUCED_DIRECT
Exemplo n.º 2
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                      translation=[4 * math.sqrt(2), 2.],
                      orientation=[math.pi / 4.0],
                      velocity=[0, 0, -1.0],
                      mass=1.,
                      inertia=2.0)

        # the ground object made with the ground shape. As the mass is
        # not given, it is a static object only involved in contact
        # detection.
        io.add_object('ground', [Contactor('Ground')], translation=[0, -.5])

# Run the simulation from the inputs previously defined and add
# results to the hdf5 file. The visualisation of the output may be done
# with the vview command.

bullet_options = SiconosBulletOptions()
bullet_options.worldScale = 1.0
bullet_options.contactBreakingThreshold = 0.04
bullet_options.dimension = SICONOS_BULLET_2D
bullet_options.perturbationIterations = 0
bullet_options.minimumPointsPerturbationThreshold = 0

options = sk.solver_options_create(sn.SICONOS_FRICTION_2D_NSGS)
options.iparam[sn.SICONOS_IPARAM_MAX_ITER] = 100000
options.dparam[sn.SICONOS_DPARAM_TOL] = 1e-8

T = 2.0
if restart:
    T = 2.0
#T=1*0.001
hstep = 0.01
Exemplo n.º 3
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# ./mkspheres.py <n>
# ./spheres_in_a_box.py coors-<n>.txt radii-<n>.txt

from siconos.mechanics.collision.tools import Contactor
from siconos.io.mechanics_run import MechanicsHdf5Runner
from siconos.io.FrictionContactTrace import FrictionContactTraceParams

import siconos.numerics as sn
import siconos.kernel as sk

from siconos.mechanics.collision.bullet import SiconosBulletOptions
from math import pi
import numpy
import sys
import mkspheres
bullet_options = SiconosBulletOptions()
bullet_options.worldScale = 1000
bullet_options.contactBreakingThreshold = 0.0002
bullet_options.perturbationIterations = 0
bullet_options.minimumPointsPerturbationThreshold = 0
hstep = 0.001
theta = 0.50001
itermax = 1000
tolerance = 1e-7
lx = mkspheres.lx
ly = mkspheres.ly
lz = mkspheres.lz
margin_ratio=1.e-5
wthick = mkspheres.lz/10
zoffset = -wthick/2
Exemplo n.º 4
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    io.add_object('disk', [Contactor('Disk')],
                  translation=[0, 5.],
                  velocity=[0, 0, 0.5],
                  mass=1.,
                  inertia=2.0)

    # the ground object made with the ground shape. As the mass is
    # not given, it is a static object only involved in contact
    # detection.
    io.add_object('ground', [Contactor('Ground_disk')], translation=[0, -4.0])

# Run the simulation from the inputs previously defined and add
# results to the hdf5 file. The visualisation of the output may be done
# with the vview command.

bullet_options = SiconosBulletOptions()
bullet_options.worldScale = 1.0
bullet_options.contactBreakingThreshold = 0.04
bullet_options.dimension = 1

options = sk.solver_options_create(sn.SICONOS_FRICTION_2D_NSGS)
options.iparam[sn.SICONOS_IPARAM_MAX_ITER] = 100000
options.dparam[sn.SICONOS_DPARAM_TOL] = 1e-8

with MechanicsHdf5Runner(mode='r+') as io:

    # By default earth gravity is applied and the units are those
    # of the International System of Units.
    io.run(verbose=True,
           with_timer=False,
           bullet_options=bullet_options,
Exemplo n.º 5
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#!/usr/bin/env python

# Various object types sliding, rolling, and sitting still.

from siconos.mechanics.collision.tools import Contactor
from siconos.io.mechanics_run import MechanicsHdf5Runner
from siconos.mechanics.collision.convexhull import ConvexHull

from siconos.mechanics.collision.bullet import SiconosBulletOptions
import siconos.numerics as sn
import siconos.kernel as sk

bullet_options = SiconosBulletOptions()
bullet_options.worldScale = 1.0

# Control the number of perturbations applied to generate multipoint
# surface-surface contact manifolds.  Default is 5 and 5.
bullet_options.perturbationIterations = 5
bullet_options.minimumPointsPerturbationThreshold = 5

# Creation of the hdf5 file for input/output
with MechanicsHdf5Runner() as io:

    # Definition of a tetrahedron as a convex shape.
    # Bottom purposely not even.
    import numpy
    pts = numpy.array([(-1.0, 1.0, -1.0), (1.0, -1.0, -0.5),
                       (-1.0, -1.0, -0.7), (0.0, 0.0, 1.0)])
    io.add_convex_shape('Tetra', pts - pts.mean(0))

    io.add_primitive_shape('Cyl', 'Cylinder', [1, 1])
Exemplo n.º 6
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#!/usr/bin/env python

#
# Example of one object under gravity with one contactor and a ground
# using the Siconos proposed mechanics API
#

from siconos.mechanics.collision.tools import Contactor
from siconos.io.mechanics_io import Hdf5
import siconos.numerics as Numerics
import siconos.io.mechanics_io
from siconos.mechanics.collision.bullet import SiconosBulletOptions

options = SiconosBulletOptions()
options.worldScale = 1.0
options.contactBreakingThreshold = 0.04

# Creation of the hdf5 file for input/output
with Hdf5() as io:

    # Definition of a sphere
    io.addPrimitiveShape('Sphere',
                         'Sphere', (2, ),
                         insideMargin=0.2,
                         outsideMargin=0.3)

    # Definition of the ground shape
    io.addPrimitiveShape('Ground',
                         'Box', (10, 10, 0.1),
                         insideMargin=0.05,
                         outsideMargin=0.1)
Exemplo n.º 7
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# oscillation if integrated with a fully implicit version of the
# classical time-stepping method. Reducing the step-size led to
# different results as the divergence or deadening was weakened."

mu = 0.3
m = 6*1e-3     # kg
r1 = 1.5       # cm
r2 = 0.5       # cm
a1 = 0.3       # cm
a2 = 1.6       # cm
I1 = 8*1e-3    # kg . cm^2
I3 = 7*1e-3    # kg . cm^2

# Bullet: do not generate extra contact points for convex pairs by
# rotational purterbation method.
bullet_options = SiconosBulletOptions()
bullet_options.perturbationIterations = 0
bullet_options.minimumPointsPerturbationThreshold = 0

with MechanicsHdf5Runner() as io:

    io.add_primitive_shape('Body1', 'Sphere', (r1,))
    io.add_primitive_shape('Body2', 'Cylinder', (r2, a2))
    io.add_primitive_shape('Body3', 'Sphere', (r2,))
    io.add_primitive_shape('Ground', 'Box', (100, 100, .5))

    io.add_Newton_impact_friction_nsl('contact', mu=mu)
    io.add_object('ground', [Contactor('Ground')], translation=[0, 0, 0])

    io.add_object('tippe-top', [Contactor('Body1',
                                          relative_translation=[0, 0, a1]),
Exemplo n.º 8
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#
# Here we demonstrate the use of two very small cubes simulated with
# geometry at 1000x its scale.  Without scaling, contact detection is
# incorrect for an object of this size.  When contact detection is
# performed with scaled-up geometries, the contact points are
# correctly generated and used by Siconos.
#

from siconos.mechanics.collision.tools import Contactor
from siconos.io.mechanics_run import MechanicsHdf5Runner
import siconos.numerics as Numerics

# We need to pass some options to the Bullet backend
from siconos.mechanics.collision.bullet import SiconosBulletOptions
options = SiconosBulletOptions()
options.worldScale = 1000.0

# Creation of the hdf5 file for input/output
with MechanicsHdf5Runner() as io:

    # Definition of a cube as a convex shape
    io.add_convex_shape('CubeCH',
                        [(-0.001, 0.001, -0.001), (-0.001, -0.001, -0.001),
                         (-0.001, -0.001, 0.001), (-0.001, 0.001, 0.001),
                         (0.001, 0.001, 0.001), (0.001, 0.001, -0.001),
                         (0.001, -0.001, -0.001), (0.001, -0.001, 0.001)])

    # Definition of a cube as a primitive shape
    io.add_primitive_shape('CubeP', 'Box', (0.002, 0.002, 0.002))
Exemplo n.º 9
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    io.add_object('cubeP', [Contactor('CubeP')],
                  translation=[0, -0.003, 0.005],
                  velocity=[0.1, 0, 0, 1, 1, 1],
                  mass=0.1)

    # the ground object made with the ground shape. As the mass is
    # not given, it is a static object only involved in contact
    # detection.
    io.add_object('ground', [Contactor('Ground')], translation=[0, 0, -0.005])

# Run the simulation from the inputs previously defined and add
# results to the hdf5 file. The visualisation of the output may be done
# with the vview command.

from siconos.mechanics.collision.bullet import SiconosBulletOptions
bullet_options = SiconosBulletOptions()
bullet_options.worldScale = 1000.0
bullet_options.contactBreakingThreshold = 0.001

options = sk.solver_options_create(sn.SICONOS_FRICTION_3D_NSGS)
options.iparam[sn.SICONOS_IPARAM_MAX_ITER] = 10000
options.dparam[sn.SICONOS_DPARAM_TOL] = 1e-8

with MechanicsHdf5Runner(mode='r+') as io:

    # By default earth gravity is applied and the units are those
    # of the International System of Units.
    # Because of fixed collision margins used in the collision detection,
    # sizes of small objects may need to be expressed in cm or mm.
    io.run(with_timer=False,
           bullet_options=bullet_options,