예제 #1
0
# link the interaction and the dynamical system
impactingBar.link(inter,bar);


# ------------------
# --- Simulation ---
# ------------------

# -- (1) OneStepIntegrators --
OSI = MoreauJeanOSI(theta,0.5)

# -- (2) Time discretisation --
t = TimeDiscretisation(t0,h)

# -- (3) one step non smooth problem
osnspb = LCP()

s = TimeStepping(impactingBar, t,OSI,osnspb)

k =0

N = int((T-t0)/h)
dataPlot = np.zeros((N+1, 5))

q = bar.q()
v = bar.velocity()
p = bar.p(1)
lambda_ = inter.lambda_(1)

# time loop
while s.hasNextEvent():
예제 #2
0
def test_bouncing_ball1():

    from siconos.kernel import LagrangianLinearTIDS, NewtonImpactNSL, \
        LagrangianLinearTIR, Interaction, Model, MoreauJeanOSI, TimeDiscretisation, LCP, TimeStepping

    from numpy import array, eye, empty

    t0 = 0       # start time
    T = 10       # end time
    h = 0.005    # time step
    r = 0.1      # ball radius
    g = 9.81     # gravity
    m = 1        # ball mass
    e = 0.9      # restitution coeficient
    theta = 0.5  # theta scheme

    #
    # dynamical system
    #
    x = array([1, 0, 0])  # initial position
    v = array([0, 0, 0])  # initial velocity
    mass = eye(3)         # mass matrix
    mass[2, 2] = 3./5 * r * r

    # the dynamical system
    ball = LagrangianLinearTIDS(x, v, mass)

    # set external forces
    weight = array([-m * g, 0, 0])
    ball.setFExtPtr(weight)

    #
    # Interactions
    #

    # ball-floor
    H = array([[1, 0, 0]])

    nslaw = NewtonImpactNSL(e)
    relation = LagrangianLinearTIR(H)
    inter = Interaction(1, nslaw, relation)

    #
    # Model
    #
    bouncingBall = Model(t0, T)

    # add the dynamical system to the non smooth dynamical system
    bouncingBall.nonSmoothDynamicalSystem().insertDynamicalSystem(ball)

    # link the interaction and the dynamical system
    bouncingBall.nonSmoothDynamicalSystem().link(inter, ball)

    #
    # Simulation
    #

    # (1) OneStepIntegrators
    OSI = MoreauJeanOSI(theta)
    OSI.insertDynamicalSystem(ball)

    # (2) Time discretisation --
    t = TimeDiscretisation(t0, h)

    # (3) one step non smooth problem
    osnspb = LCP()

    # (4) Simulation setup with (1) (2) (3)
    s = TimeStepping(t)
    s.insertIntegrator(OSI)
    s.insertNonSmoothProblem(osnspb)

    # end of model definition

    #
    # computation
    #

    # simulation initialization
    bouncingBall.initialize(s)

    #
    # save and load data from xml and .dat
    #
    try:
        from siconos.io import save
        save(bouncingBall, "bouncingBall.xml")
        save(bouncingBall, "bouncingBall.bin")

    except:
        print("Warning : could not import save from siconos.io")

    # the number of time steps
    N = (T-t0)/h+1

    # Get the values to be plotted
    # ->saved in a matrix dataPlot

    dataPlot = empty((N, 5))

    #
    # numpy pointers on dense Siconos vectors
    #
    q = ball.q()
    v = ball.velocity()
    p = ball.p(1)
    lambda_ = inter.lambda_(1)

    #
    # initial data
    #
    dataPlot[0, 0] = t0
    dataPlot[0, 1] = q[0]
    dataPlot[0, 2] = v[0]
    dataPlot[0, 3] = p[0]
    dataPlot[0, 4] = lambda_[0]

    k = 1

    # time loop
    while(s.hasNextEvent()):
        s.computeOneStep()

        dataPlot[k, 0] = s.nextTime()
        dataPlot[k, 1] = q[0]
        dataPlot[k, 2] = v[0]
        dataPlot[k, 3] = p[0]
        dataPlot[k, 4] = lambda_[0]

        k += 1
        #print(s.nextTime())
        s.nextStep()

    #
    # comparison with the reference file
    #
    from siconos.kernel import SimpleMatrix, getMatrix
    from numpy.linalg import norm

    ref = getMatrix(SimpleMatrix(os.path.join(working_dir, "data/result.ref")))

    assert (norm(dataPlot - ref) < 1e-12)
예제 #3
0
#
# Simulation
#

# (1) OneStepIntegrators
theta = 0.5
gamma = 0.5
aOSI = EulerMoreauOSI(theta, gamma)
aOSI.insertDynamicalSystem(LSDiodeBridge)
#aOSI.setUseGammaForRelation(True)

# (2) Time discretisation
aTiDisc = TimeDiscretisation(t0, h_step)

# (3) Non smooth problem
aLCP = LCP()

# (4) Simulation setup with (1) (2) (3)
aTS = TimeStepping(aTiDisc, aOSI, aLCP)

# end of model definition

#
# computation
#

# simulation initialization
DiodeBridge.initialize(aTS)

k = 0
h = aTS.timeStep()
예제 #4
0
def test_diode_bridge():
    """Build diode bridge model"""
    # dynamical system
    bridge_ds = FirstOrderLinearDS(init_state, A)
    # interaction
    diode_bridge_relation = FirstOrderLinearTIR(C, B)
    diode_bridge_relation.setDPtr(D)

    nslaw = ComplementarityConditionNSL(4)
    bridge_interaction = Interaction(4, nslaw, diode_bridge_relation, 1)

    # Model
    diode_bridge = Model(t0, total_time, model_title)

    #  add the dynamical system in the non smooth dynamical system
    diode_bridge.nonSmoothDynamicalSystem().insertDynamicalSystem(bridge_ds)

    #   link the interaction and the dynamical system
    diode_bridge.nonSmoothDynamicalSystem().link(bridge_interaction, bridge_ds)

    # Simulation

    # (1) OneStepIntegrators
    theta = 0.5
    integrator = EulerMoreauOSI(theta)
    integrator.insertDynamicalSystem(bridge_ds)

    # (2) Time discretisation
    time_discretisation = TimeDiscretisation(t0, time_step)

    # (3) Non smooth problem
    non_smooth_problem = LCP()

    # (4) Simulation setup with (1) (2) (3)
    bridge_simulation = TimeStepping(time_discretisation, integrator,
                                     non_smooth_problem)

    # simulation initialization
    diode_bridge.initialize(bridge_simulation)
    k = 0
    h = bridge_simulation.timeStep()
    # Number of time steps
    N = (total_time - t0) / h

    # Get the values to be plotted
    # ->saved in a matrix dataPlot
    data_plot = empty([N, 8])

    x = bridge_ds.x()
    print("Initial state : ", x)
    y = bridge_interaction.y(0)
    print("First y : ", y)
    lambda_ = bridge_interaction.lambda_(0)

    # For the initial time step:
    # time
    data_plot[k, 0] = t0

    #  inductor voltage
    data_plot[k, 1] = x[0]

    # inductor current
    data_plot[k, 2] = x[1]

    # diode R1 current
    data_plot[k, 3] = y[0]

    # diode R1 voltage
    data_plot[k, 4] = -lambda_[0]

    # diode F2 voltage
    data_plot[k, 5] = -lambda_[1]

    # diode F1 current
    data_plot[k, 6] = lambda_[2]

    # resistor current
    data_plot[k, 7] = y[0] + lambda_[2]

    k += 1
    while k < N:
        bridge_simulation.computeOneStep()
        #non_smooth_problem.display()
        data_plot[k, 0] = bridge_simulation.nextTime()
        #  inductor voltage
        data_plot[k, 1] = x[0]
        # inductor current
        data_plot[k, 2] = x[1]
        # diode R1 current
        data_plot[k, 3] = y[0]
        # diode R1 voltage
        data_plot[k, 4] = -lambda_[0]
        # diode F2 voltage
        data_plot[k, 5] = -lambda_[1]
        # diode F1 current
        data_plot[k, 6] = lambda_[2]
        # resistor current
        data_plot[k, 7] = y[0] + lambda_[2]
        k += 1
        bridge_simulation.nextStep()

    #
    # comparison with the reference file
    #
    ref = getMatrix(
        SimpleMatrix(os.path.join(working_dir, "data/diode_bridge.ref")))
    assert norm(data_plot - ref) < 1e-12
    return ref, data_plot