def test_rigidbody_defaults(): mass = 1.5 moment_of_inertia = np.diag([13.2e-3, 12.8e-3, 24.6e-3]) system = System() rb_6dof = RigidBody6DOFFlatEarth(owner=system, mass=mass, moment_of_inertia=moment_of_inertia) dcm_to_euler = DirectCosineToEuler(system) thrust = constant(value=np.r_[0, 0, 0]) moment = constant(value=moment_of_inertia @ np.r_[0, 0, math.pi / 30**2]) thrust.connect(rb_6dof.forces_body) moment.connect(rb_6dof.moments_body) rb_6dof.dcm.connect(dcm_to_euler.dcm) rtol = 1e-12 atol = 1e-12 sim = Simulator(system, start_time=0, rtol=rtol, atol=atol) *_, last_item = sim.run_until(time_boundary=30.0, include_last=True) npt.assert_allclose(dcm_to_euler.yaw(last_item), math.pi / 2, rtol=rtol, atol=atol) npt.assert_allclose(dcm_to_euler.pitch(last_item), 0, rtol=rtol, atol=atol) npt.assert_allclose(dcm_to_euler.roll(last_item), 0, rtol=rtol, atol=atol) npt.assert_allclose(rb_6dof.position_earth(last_item), [0, 0, 0], rtol=rtol, atol=atol)
def test_deprecated_options(): """Test if deprecated options lead to warnings""" system = System() with pytest.warns(DeprecationWarning): Simulator(system, start_time=0, event_xtol=1e-12) with pytest.warns(DeprecationWarning): Simulator(system, start_time=0, event_maxiter=1000)
def test_lti_simulation_failure(lti_system_with_reference): sys, ref_function, sim_time, outputs = lti_system_with_reference del ref_function, outputs # unused simulator = Simulator(sys, start_time=0, solver_method=MockupIntegrator) with pytest.raises(SimulationError): for _ in simulator.run_until(sim_time): pass
def test_clock_handling(): """Test the handling of clocks in the simulator.""" time_constant = 1.0 initial_value = 2.0 system = System() input_signal = constant(value=0.0) lag = LTISystem( parent=system, system_matrix=-1 / time_constant, input_matrix=1, output_matrix=1, feed_through_matrix=0, initial_condition=[initial_value], ) lag.input.connect(input_signal) clock1 = Clock(system, period=0.2) hold1 = zero_order_hold( system, input_port=lag.output, event_port=clock1, initial_condition=initial_value, ) clock2 = Clock(system, period=0.25, end_time=2.0) hold2 = zero_order_hold( system, input_port=lag.output, event_port=clock2, initial_condition=initial_value, ) # Clock 3 will not fire within the simulation time frame clock3 = Clock(system, period=0.25, start_time=-6.0, end_time=-1.0) hold3 = zero_order_hold( system, input_port=lag.output, event_port=clock3, initial_condition=initial_value, ) simulator = Simulator(system, start_time=0.0) result = SimulationResult(system, simulator.run_until(time_boundary=5.0)) time_floor1 = np.floor(result.time / clock1.period) * clock1.period time_floor2 = np.minimum( clock2.end_time, (np.floor(result.time / clock2.period) * clock2.period)) reference1 = initial_value * np.exp(-time_floor1 / time_constant) reference2 = initial_value * np.exp(-time_floor2 / time_constant) npt.assert_almost_equal(hold1(result), reference1) npt.assert_almost_equal(hold2(result), reference2) npt.assert_almost_equal(hold3(result), initial_value)
def test_integrator(): """Test an integrator""" system = System() int_input = constant(1.0) int_output = integrator(system, int_input) simulator = Simulator(system, start_time=0.0) result = SimulationResult(system, simulator.run_until(time_boundary=10.0)) npt.assert_almost_equal(int_output(result).ravel(), result.time)
def test_lti_simulation(lti_system_with_reference): sys, ref_system, ref_time, _ = lti_system_with_reference rtol = 1e-12 atol = 1e-12 simulator = Simulator(sys, start_time=0, rtol=rtol, atol=atol) result = SimulationResult(sys) result.collect_from( simulator.run_until(time_boundary=ref_time / 2, include_last=False)) result.collect_from( simulator.run_until(time_boundary=ref_time, include_last=False)) # Check that states are properly mapped in the result for state in sys.states: from_result = result.state[state.state_slice] from_result = from_result.reshape(state.shape + (-1, )) npt.assert_equal(state(result), from_result) # Check that inputs are properly mapped in the result for input_signal in sys.inputs: from_result = result.inputs[input_signal.input_slice] from_result = from_result.reshape(input_signal.shape + (-1, )) npt.assert_equal(input_signal(result), from_result) # Determine the system response and state values of the reference system ref_time, ref_output, ref_state = scipy.signal.lsim2( ref_system, X0=sys.initial_condition, T=result.time, U=None, rtol=rtol, atol=atol, ) del ref_output # Determine the state values at the simulated times # as per the reference value npt.assert_allclose(ref_time, result.time, rtol=rtol, atol=atol) # FIXME: These factors are somewhat arbitrary npt.assert_allclose(result.state, ref_state.T, rtol=rtol * 1e2, atol=atol * 1e2) # Check that SimulationResult properly implements the sequence interface assert len(result) == len(result.time) for idx, item in enumerate(result): npt.assert_equal(item.time, result.time[idx]) npt.assert_equal(item.state, result.state[:, idx]) npt.assert_equal(item.inputs, result.inputs[:, idx])
def test_saturation(): system = System() Clock(system, period=0.01) @signal_function def _sine_source(system_state): return np.sin(2 * np.pi * system_state.time) saturated_out = saturation(_sine_source, lower_limit=-0.5, upper_limit=0.6) simulator = Simulator(system, start_time=0.0) result = SimulationResult(system, simulator.run_until(time_boundary=1.0)) sine_data = _sine_source(result) saturated_data = saturated_out(result) saturated_exp = np.minimum(np.maximum(sine_data, -0.5), 0.6) npt.assert_almost_equal(saturated_data, saturated_exp)
def test_rigidbody_movement(): mass = 1.5 omega = 2 * math.pi / 120 r = 10.0 vx = r * omega moment_of_inertia = np.diag([13.2e-3, 12.8e-3, 24.6e-3]) system = System() rb_6dof = RigidBody6DOFFlatEarth( owner=system, mass=mass, initial_velocity_earth=[vx, 0, 0], initial_angular_rates_earth=[0, 0, omega], initial_position_earth=[0, 0, 0], initial_transformation=np.eye(3, 3), moment_of_inertia=moment_of_inertia, ) dcm_to_euler = DirectCosineToEuler(system) thrust = constant(value=np.r_[0, mass * omega * vx, 0]) moment = constant(value=np.r_[0, 0, 0]) thrust.connect(rb_6dof.forces_body) moment.connect(rb_6dof.moments_body) rb_6dof.dcm.connect(dcm_to_euler.dcm) rtol = 1e-12 atol = 1e-12 sim = Simulator(system, start_time=0, rtol=rtol, atol=atol) *_, last_item = sim.run_until(time_boundary=30.0, include_last=True) npt.assert_allclose(dcm_to_euler.yaw(last_item), math.pi / 2, rtol=rtol, atol=atol) npt.assert_allclose(dcm_to_euler.pitch(last_item), 0, rtol=rtol, atol=atol) npt.assert_allclose(dcm_to_euler.roll(last_item), 0, rtol=rtol, atol=atol) npt.assert_allclose(rb_6dof.position_earth(last_item), [r, r, 0], rtol=rtol, atol=atol) npt.assert_allclose(rb_6dof.velocity_body(last_item), [vx, 0, 0], rtol=rtol, atol=atol) npt.assert_allclose(rb_6dof.omega_body(last_item), [0, 0, omega], rtol=rtol, atol=atol)
def test_zero_crossing_event_detection(): """Test the detection of zero-crossing events.""" x0 = 0 y0 = 10 vx0 = 1 vy0 = 0 g = 9.81 gamma = 0.7 system = System() bouncing_ball = BouncingBall(parent=system, gravity=-g, gamma=gamma) initial_condition = np.empty(system.num_states) initial_condition[bouncing_ball.velocity.state_slice] = [vx0, vy0] initial_condition[bouncing_ball.position.state_slice] = [x0, y0] simulator = Simulator( system, start_time=0, initial_condition=initial_condition, max_step=0.05, event_detector_options={"max_subdiv": 10}, ) result = SimulationResult(system, simulator.run_until(time_boundary=8.0)) # Determine the time of the first impact t_impact = (2 * vy0 + math.sqrt(4 * vy0**2 + 8 * g * y0)) / (2 * g) # Check that the y-component of velocity changes sign around time of impact t_tolerance = 0.1 idx_start = bisect.bisect_left(result.time, t_impact - t_tolerance) idx_end = bisect.bisect_left(result.time, t_impact + t_tolerance) assert result.time[idx_start] < t_impact assert result.time[idx_end] >= t_impact vy = bouncing_ball.velocity(result)[1][idx_start:idx_end] sign_change = np.sign(vy[:-1]) != np.sign(vy[1:]) assert any(sign_change) # Check detection of excessive event error with pytest.raises(ExcessiveEventError): for _ in simulator.run_until(time_boundary=10.0): pass
def test_system_state_updater_dictionary_access(): """Test the deprecated dictionary access for simulation results""" system = System() counter = State(system, shape=(2, 2)) clock = Clock(system, 1.0) def _update_counter(system_state): old_val = counter(system_state).copy() system_state[counter] += 1 system_state[counter, 0] += 1 system_state[counter, 0, 0] += 1 new_val = counter(system_state) npt.assert_almost_equal(old_val + [[3, 2], [1, 1]], new_val) clock.register_listener(_update_counter) simulator = Simulator(system, start_time=0) for _ in simulator.run_until(time_boundary=10): pass
def test_excessive_events_second_level(): """Test the detection of excessive events when it is introduced by toggling the same event over and over.""" system = System() state = State(system, derivative_function=(lambda data: -1), initial_condition=5) event = ZeroCrossEventSource(system, event_function=state) def event_handler(data): """Event handler for the zero-crossing event""" state.set_value(data, -state(data)) event.register_listener(event_handler) simulator = Simulator(system, start_time=0) with pytest.raises(ExcessiveEventError): for _ in simulator.run_until(6): pass
def test_discrete_only(): """Test a system with only discrete-time states.""" system = System() clock = Clock(system, period=1.0) counter = State(system) def increase_counter(data): """Increase the counter whenever a clock event occurs""" counter.set_value(data, counter(data) + 1) clock.register_listener(increase_counter) simulator = Simulator(system, start_time=0.0) result = SimulationResult(system) result.collect_from(simulator.run_until(5.5, include_last=False)) result.collect_from(simulator.run_until(10)) npt.assert_almost_equal(result.time, [0, 1, 2, 3, 4, 5, 5.5, 6, 7, 8, 9, 10]) npt.assert_almost_equal(counter(result), [1, 2, 3, 4, 5, 6, 6, 7, 8, 9, 10, 11])
dcm_to_euler = DirectCosineToEuler(system) # We provide some thrust as centripetal force thrust = constant(value=np.r_[0, MASS * OMEGA * VELOCITY_X, 0]) # No torques torque = constant(value=np.r_[0, 0, 0]) # Connect thrust and torque to the rigid-body block thrust.connect(rb_6dof.forces_body) torque.connect(rb_6dof.moments_body) # Connect the Direct Cosine Matrix output to the Euler conversion block rb_6dof.dcm.connect(dcm_to_euler.dcm) # Simulate the system for 2 minutes sim = Simulator(system, start_time=0, max_step=0.1) result = SimulationResult(system, sim.run_until(time_boundary=120.0)) # Plot the Euler angles fig_euler, (ax_yaw, ax_pitch, ax_roll) = plt.subplots(nrows=3, sharex="row") ax_yaw.plot(result.time, np.rad2deg(dcm_to_euler.yaw(result))) ax_pitch.plot(result.time, np.rad2deg(dcm_to_euler.pitch(result))) ax_roll.plot(result.time, np.rad2deg(dcm_to_euler.roll(result))) ax_yaw.set_title("Yaw") ax_pitch.set_title("Pitch") ax_roll.set_title("Roll") # Plot the trajectory in top view fig_top_view, ax = plt.subplots() position = rb_6dof.position_earth(result) ax.plot(position[0], position[1])
# Create the states velocity = State( owner=system, shape=2, derivative_function=velocity_dt, initial_condition=V_0, ) position = State(owner=system, shape=2, derivative_function=velocity, initial_condition=X_0) # Run a simulation simulator = Simulator(system, start_time=0.0, max_step=24 * 60 * 60) result = SimulationResult(system, simulator.run_until(time_boundary=ROTATION_TIME)) # Plot the result trajectory = position(result) plt.plot(trajectory[0], trajectory[1]) plt.gca().set_aspect("equal", "box") plt.title("Planet Orbit") plt.savefig("03_planet_orbit_trajectory.png") plt.figure() plt.plot(result.time, linalg.norm(trajectory, axis=0)) plt.xlabel("Time (s)") plt.ylabel("Distance from the Sun (m)") plt.title("Distance Earth-Sun over Time")
# Set up the state for keeping the sampled value. sample_state = State(system) # Create a clock for sampling at 100Hz sample_clock = Clock(system, period=0.01) # Define the function for updating the state def update_sample(system_state): """Update the state of the sampler""" sample_state.set_value(system_state, engine.thrust(system_state)) # Register it as event handler on the clock sample_clock.register_listener(update_sample) # Create the simulator and run it simulator = Simulator(system, start_time=0.0) result = SimulationResult(system, simulator.run_until(time_boundary=0.5)) # Plot the result plt.plot(result.time, engine.thrust(result), "r", label="Continuous-Time") plt.step(result.time, sample_state(result), "g", label="Sampled", where="post") plt.title("Engine with DC-Motor and Static Propeller") plt.legend() plt.xlabel("Time") plt.ylabel("Thrust") plt.savefig("06_dc_engine_sampling.png") plt.show()
# The system states def velocity_dt(_system_state): """Calculate the derivative of the vertical speed""" return -G velocity = State(system, derivative_function=velocity_dt, initial_condition=INITIAL_VELOCITY) height = integrator(system, input_signal=velocity, initial_condition=INITIAL_HEIGHT) # Run a simulation without event handler simulator = Simulator(system=system, start_time=0, max_step=0.1) result = SimulationResult(system=system) result.collect_from(simulator.run_until(time_boundary=2)) # Plot the simulation result plt.plot(result.time, height(result)) plt.xlabel("Time (s)") plt.ylabel("Height (m)") plt.title("Falling Ball") plt.grid(axis="y") plt.savefig("04_bouncing_ball_no_event.png") # Define a zero-crossing event for the height bounce_event = ZeroCrossEventSource(system, event_function=height, direction=-1)