Exemplo n.º 1
0
    def test_mesh_file_parsing(self):
        """
        This test ensures we can load obj files or provide a reasonable error
        message.
        """
        def scene_graph_with_mesh(filename):
            builder = DiagramBuilder()
            mbp, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
            world_body = mbp.world_body()

            mesh_shape = Mesh(filename)
            mesh_body = mbp.AddRigidBody(
                "mesh",
                SpatialInertia(mass=1.0,
                               p_PScm_E=np.array([0., 0., 0.]),
                               G_SP_E=UnitInertia(1.0, 1.0, 1.0)))
            mbp.WeldFrames(world_body.body_frame(), mesh_body.body_frame(),
                           RigidTransform())
            mbp.RegisterVisualGeometry(mesh_body, RigidTransform.Identity(),
                                       mesh_shape, "mesh_vis",
                                       np.array([0.5, 0.5, 0.5, 1.]))
            mbp.Finalize()

            return scene_graph

        # This mesh should load correctly.
        mesh_name = FindResourceOrThrow(
            "drake/manipulation/models/iiwa_description/meshes/visual/"
            "link_0.obj")
        scene_graph = scene_graph_with_mesh(mesh_name)
        PlanarSceneGraphVisualizer(scene_graph)

        # This should load correctly, too, by substituting the .obj.
        mesh_name_wrong_ext = os.path.splitext(mesh_name)[0] + ".STL"
        scene_graph = scene_graph_with_mesh(mesh_name_wrong_ext)
        PlanarSceneGraphVisualizer(scene_graph)

        # This should report that the file does not exist:
        with self.assertRaises(FileNotFoundError):
            PlanarSceneGraphVisualizer(scene_graph,
                                       substitute_collocated_mesh_files=False)

        # This should report that the file does not exist.
        scene_graph = scene_graph_with_mesh("garbage.obj")
        with self.assertRaises(FileNotFoundError):
            PlanarSceneGraphVisualizer(scene_graph)

        # This should report that the extension was wrong and no .obj was
        # found.
        scene_graph = scene_graph_with_mesh("garbage.STL")
        with self.assertRaises(RuntimeError):
            PlanarSceneGraphVisualizer(scene_graph)
Exemplo n.º 2
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def run_pendulum_example(args):
    builder = DiagramBuilder()
    plant, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
    parser = Parser(plant)
    parser.AddModelFromFile(
        FindResourceOrThrow("drake/examples/pendulum/Pendulum.urdf"))
    plant.WeldFrames(plant.world_frame(), plant.GetFrameByName("base"))
    plant.Finalize()

    pose_bundle_output_port = scene_graph.get_pose_bundle_output_port()
    Tview = np.array([[1., 0., 0., 0.], [0., 0., 1., 0.], [0., 0., 0., 1.]],
                     dtype=np.float64)
    visualizer = builder.AddSystem(
        PlanarSceneGraphVisualizer(scene_graph,
                                   T_VW=Tview,
                                   xlim=[-1.2, 1.2],
                                   ylim=[-1.2, 1.2]))
    builder.Connect(pose_bundle_output_port, visualizer.get_input_port(0))

    diagram = builder.Build()
    simulator = Simulator(diagram)
    simulator.Initialize()
    simulator.set_target_realtime_rate(1.0)

    # Fix the input port to zero.
    plant_context = diagram.GetMutableSubsystemContext(
        plant, simulator.get_mutable_context())
    plant_context.FixInputPort(plant.get_actuation_input_port().get_index(),
                               np.zeros(plant.num_actuators()))
    plant_context.SetContinuousState([0.5, 0.1])
    simulator.AdvanceTo(args.duration)
Exemplo n.º 3
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    def test_cart_pole(self):
        """Cart-Pole with simple geometry."""
        file_name = FindResourceOrThrow(
            "drake/examples/multibody/cart_pole/cart_pole.sdf")
        builder = DiagramBuilder()
        cart_pole, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
        Parser(plant=cart_pole).AddModelFromFile(file_name)
        cart_pole.Finalize()
        self.assertTrue(cart_pole.geometry_source_is_registered())

        visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(scene_graph))
        builder.Connect(scene_graph.get_pose_bundle_output_port(),
                        visualizer.get_input_port(0))

        diagram = builder.Build()

        diagram_context = diagram.CreateDefaultContext()
        cart_pole_context = diagram.GetMutableSubsystemContext(
            cart_pole, diagram_context)
        vis_context = diagram.GetMutableSubsystemContext(
            visualizer, diagram_context)

        cart_pole.get_actuation_input_port().FixValue(cart_pole_context, 0)

        cart_slider = cart_pole.GetJointByName("CartSlider")
        pole_pin = cart_pole.GetJointByName("PolePin")
        cart_slider.set_translation(context=cart_pole_context, translation=0.)
        pole_pin.set_angle(context=cart_pole_context, angle=2.)

        simulator = Simulator(diagram, diagram_context)
        simulator.set_publish_every_time_step(False)
        simulator.AdvanceTo(.1)

        visualizer.draw(vis_context)
        self.assertEqual(visualizer.ax.get_title(), "t = 0.1",)
def pendulum_example(duration=1., playback=True, show=True):
    """
        Simulate the pendulum
        
        Arguments:
            duration: Simulation duration (sec) 
            playback: enable pyplot animations
    """
    # To make a visualization, we have to attach a multibody plant, a scene graph, and a visualizer together. In Drake, we can connect all these systems together in a Diagram.
    builder = DiagramBuilder()
    # AddMultibodyPlantSceneGraph: Adds a multibody plant and scene graph to the Diagram, and connects their geometry ports. The second input is the timestep for MultibodyPlant
    plant, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.)
    # Now we create the plant model from a file
    parser = Parser(plant)
    parser.AddModelFromFile(
        FindResourceOrThrow("drake/examples/pendulum/Pendulum.urdf"))
    plant.WeldFrames(plant.world_frame(), plant.GetFrameByName("base"))
    plant.Finalize()
    # The SceneGraph port that communicates with the visualizer is the pose bundle output port. A PoseBundle is just a set of poses in SE(3) and a set of frame velocities, expressed in the world frame, used for rendering.
    pose_bundle_output_port = scene_graph.get_pose_bundle_output_port()
    # T_VW is the projection matrix from view coordinates to world coordinates
    T_VW = np.array([[1., 0., 0., 0.], [0., 0., 1., 0.], [0., 0., 0., 1.]])
    # Now we add a planar visualizer to the the diagram, so we can see the results
    visualizer = builder.AddSystem(
        PlanarSceneGraphVisualizer(scene_graph,
                                   T_VW=T_VW,
                                   xlim=[-1.2, 1.2],
                                   ylim=[-1.2, 1.2],
                                   show=show))
    # finally, we must connect the scene_graph to the visualizer so they can communicate
    builder.Connect(pose_bundle_output_port, visualizer.get_input_port(0))

    if playback:
        visualizer.start_recording()
    # To finalize the diagram, we build it
    diagram = builder.Build()
    # We create a simulator of our diagram to step through the diagram in time
    simulator = Simulator(diagram)
    # Initialize prepares the simulator for simulation
    simulator.Initialize()
    # Slow down the simulator to realtime. Otherwise it could run too fast
    simulator.set_target_realtime_rate(1.)
    # To set initial conditions, we modify the mutable simulator context (we could do this before Initialize)
    plant_context = diagram.GetMutableSubsystemContext(
        plant, simulator.get_mutable_context())
    plant_context.SetContinuousState([0.5, 0.1])
    # Now we fix the value of the actuation to get an unactuated simulation
    plant.get_actuation_input_port().FixValue(
        plant_context, np.zeros([plant.num_actuators()]))
    # Run the simulation to the specified duration
    simulator.AdvanceTo(duration)
    # Return an animation, if one was made
    if playback:
        visualizer.stop_recording()
        ani = visualizer.get_recording_as_animation()
        return ani
    else:
        return None
Exemplo n.º 5
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def run_pendulum_example(duration=1.0, playback=True, show=True):
    """
    Runs a simulation of a pendulum

    Arguments:
        duration: Simulation duration (sec).
        playback: Enable pyplot animations to be produced.
    """

    builder = DiagramBuilder()
    plant, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
    parser = Parser(plant)
    parser.AddModelFromFile(
        FindResourceOrThrow("drake/examples/pendulum/Pendulum.urdf"))
    plant.WeldFrames(plant.world_frame(), plant.GetFrameByName("base"))
    plant.Finalize()

    pose_bundle_output_port = scene_graph.get_pose_bundle_output_port()
    T_VW = np.array([[1., 0., 0., 0.], [0., 0., 1., 0.], [0., 0., 0., 1.]])
    visualizer = builder.AddSystem(
        PlanarSceneGraphVisualizer(scene_graph,
                                   T_VW=T_VW,
                                   xlim=[-1.2, 1.2],
                                   ylim=[-1.2, 1.2],
                                   show=show))

    builder.Connect(pose_bundle_output_port, visualizer.get_input_port(0))
    if playback:
        visualizer.start_recording()

    diagram = builder.Build()
    simulator = Simulator(diagram)
    simulator.Initialize()
    simulator.set_target_realtime_rate(1.0)

    # Fix the input port to zero
    plant_context = diagram.GetMutableSubsystemContext(
        plant, simulator.get_mutable_context())
    plant.get_actuation_input_port().FixValue(plant_context,
                                              np.zeros(plant.num_actuators()))
    plant_context.SetContinuousState([0.5, 0.1])
    simulator.AdvanceTo(duration)

    if playback:
        visualizer.stop_recording()
        ani = visualizer.get_recording_as_animation()
        return ani
    else:
        return None
Exemplo n.º 6
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    def connect_visualizers(builder, plant, scene_graph):
        # Connect this to drake_visualizer.
        DrakeVisualizer.AddToBuilder(builder=builder, scene_graph=scene_graph)

        # Connect to Meshcat.
        if args.meshcat is not None:
            meshcat_viz = ConnectMeshcatVisualizer(builder,
                                                   scene_graph,
                                                   zmq_url=args.meshcat)

        # Connect to PyPlot.
        if args.pyplot:
            pyplot = builder.AddSystem(PlanarSceneGraphVisualizer(scene_graph))
            builder.Connect(scene_graph.get_pose_bundle_output_port(),
                            pyplot.get_input_port(0))
    def test_procedural_geometry(self):
        """
        This test ensures we can draw procedurally added primitive
        geometry that is added to the world model instance (which has
        a slightly different naming scheme than geometry with a
        non-default / non-world model instance).
        """
        builder = DiagramBuilder()
        mbp, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
        world_body = mbp.world_body()
        box_shape = Box(1., 2., 3.)
        # This rigid body will be added to the world model instance since
        # the model instance is not specified.
        box_body = mbp.AddRigidBody(
            "box",
            SpatialInertia(mass=1.0,
                           p_PScm_E=np.array([0., 0., 0.]),
                           G_SP_E=UnitInertia(1.0, 1.0, 1.0)))
        mbp.WeldFrames(world_body.body_frame(), box_body.body_frame(),
                       RigidTransform())
        mbp.RegisterVisualGeometry(box_body, RigidTransform.Identity(),
                                   box_shape, "ground_vis",
                                   np.array([0.5, 0.5, 0.5, 1.]))
        mbp.RegisterCollisionGeometry(box_body, RigidTransform.Identity(),
                                      box_shape, "ground_col",
                                      CoulombFriction(0.9, 0.8))
        mbp.Finalize()

        frames_to_draw = {"world": {"box"}}
        visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(scene_graph))
        builder.Connect(scene_graph.get_pose_bundle_output_port(),
                        visualizer.get_input_port(0))

        diagram = builder.Build()

        diagram_context = diagram.CreateDefaultContext()
        vis_context = diagram.GetMutableSubsystemContext(
            visualizer, diagram_context)

        simulator = Simulator(diagram, diagram_context)
        simulator.set_publish_every_time_step(False)
        simulator.AdvanceTo(.1)

        visualizer.draw(vis_context)
        self.assertEqual(
            visualizer.ax.get_title(),
            "t = 0.1",
        )
Exemplo n.º 8
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def run_manipulation_example(args):
    builder = DiagramBuilder()
    station = builder.AddSystem(ManipulationStation(time_step=0.005))
    station.SetupManipulationClassStation()
    station.Finalize()

    plant = station.get_multibody_plant()
    scene_graph = station.get_scene_graph()
    pose_bundle_output_port = station.GetOutputPort("pose_bundle")

    # Side-on view of the station.
    T_VW = np.array([[1., 0., 0., 0.],
                     [0., 0., 1., 0.],
                     [0., 0., 0., 1.]])
    visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(
        scene_graph, T_VW=T_VW, xlim=[-0.5, 1.0], ylim=[-1.2, 1.2],
        draw_period=0.1))
    builder.Connect(pose_bundle_output_port, visualizer.get_input_port(0))

    if args.playback:
        visualizer.start_recording()

    diagram = builder.Build()
    simulator = Simulator(diagram)
    simulator.Initialize()
    simulator.set_target_realtime_rate(1.0)

    # Fix the control inputs to zero.
    station_context = diagram.GetMutableSubsystemContext(
        station, simulator.get_mutable_context())
    station.GetInputPort("iiwa_position").FixValue(
        station_context, station.GetIiwaPosition(station_context))
    station.GetInputPort("iiwa_feedforward_torque").FixValue(
        station_context, np.zeros(7))
    station.GetInputPort("wsg_position").FixValue(
        station_context, np.zeros(1))
    station.GetInputPort("wsg_force_limit").FixValue(
        station_context, [40.0])
    simulator.AdvanceTo(args.duration)

    if args.playback:
        visualizer.stop_recording()
        ani = visualizer.get_recording_as_animation()
        # Playback the recording and save the output.
        ani.save("{}/manip_playback.mp4".format(temp_directory()), fps=30)
    def test_kuka(self):
        """Kuka IIWA with mesh geometry."""
        file_name = FindResourceOrThrow(
            "drake/manipulation/models/iiwa_description/sdf/"
            "iiwa14_no_collision.sdf")
        builder = DiagramBuilder()
        kuka, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
        Parser(plant=kuka).AddModelFromFile(file_name)
        kuka.Finalize()

        # Make sure that the frames to visualize exist.
        iiwa = kuka.GetModelInstanceByName("iiwa14")
        kuka.GetFrameByName("iiwa_link_7", iiwa)
        kuka.GetFrameByName("iiwa_link_6", iiwa)

        frames_to_draw = {"iiwa14": {"iiwa_link_7", "iiwa_link_6"}}
        visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(scene_graph))
        builder.Connect(scene_graph.get_pose_bundle_output_port(),
                        visualizer.get_input_port(0))

        diagram = builder.Build()

        diagram_context = diagram.CreateDefaultContext()
        kuka_context = diagram.GetMutableSubsystemContext(
            kuka, diagram_context)
        vis_context = diagram.GetMutableSubsystemContext(
            visualizer, diagram_context)

        kuka_actuation_port = kuka.get_actuation_input_port()
        kuka_actuation_port.FixValue(kuka_context,
                                     np.zeros(kuka_actuation_port.size()))

        simulator = Simulator(diagram, diagram_context)
        simulator.set_publish_every_time_step(False)
        simulator.AdvanceTo(.1)

        visualizer.draw(vis_context)
        self.assertEqual(
            visualizer.ax.get_title(),
            "t = 0.1",
        )
Exemplo n.º 10
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def run_pendulum_example(args):
    builder = DiagramBuilder()
    plant, scene_graph = AddMultibodyPlantSceneGraph(builder, 0.0)
    parser = Parser(plant)
    parser.AddModelFromFile(FindResourceOrThrow(
        "drake/examples/pendulum/Pendulum.urdf"))
    plant.WeldFrames(plant.world_frame(), plant.GetFrameByName("base"))
    plant.Finalize()

    pose_bundle_output_port = scene_graph.get_pose_bundle_output_port()
    T_VW = np.array([[1., 0., 0., 0.],
                     [0., 0., 1., 0.],
                     [0., 0., 0., 1.]])
    visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(
        scene_graph, T_VW=T_VW, xlim=[-1.2, 1.2], ylim=[-1.2, 1.2]))
    builder.Connect(pose_bundle_output_port, visualizer.get_input_port(0))

    if args.playback:
        visualizer.start_recording()

    diagram = builder.Build()
    simulator = Simulator(diagram)
    simulator.Initialize()
    simulator.set_target_realtime_rate(1.0)

    # Fix the input port to zero.
    plant_context = diagram.GetMutableSubsystemContext(
        plant, simulator.get_mutable_context())
    plant_context.FixInputPort(
        plant.get_actuation_input_port().get_index(),
        np.zeros(plant.num_actuators()))
    plant_context.SetContinuousState([0.5, 0.1])
    simulator.AdvanceTo(args.duration)

    if args.playback:
        visualizer.stop_recording()
        ani = visualizer.get_recording_as_animation()
        # Playback the recording and save the output.
        ani.save("{}/pend_playback.mp4".format(temp_directory()), fps=30)
def run_manipulation_example(args):
    builder = DiagramBuilder()
    station = builder.AddSystem(ManipulationStation(time_step=0.005))
    station.SetupManipulationClassStation()
    station.Finalize()

    plant = station.get_multibody_plant()
    scene_graph = station.get_scene_graph()
    pose_bundle_output_port = station.GetOutputPort("pose_bundle")

    # Side-on view of the station.
    Tview = np.array([[1., 0., 0., 0.],
                      [0., 0., 1., 0.],
                      [0., 0., 0., 1.]],
                     dtype=np.float64)
    visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(
        scene_graph, T_VW=Tview, xlim=[-0.5, 1.0], ylim=[-1.2, 1.2],
        draw_period=0.1))
    builder.Connect(pose_bundle_output_port, visualizer.get_input_port(0))

    diagram = builder.Build()
    simulator = Simulator(diagram)
    simulator.Initialize()
    simulator.set_target_realtime_rate(1.0)

    # Fix the control inputs to zero.
    station_context = diagram.GetMutableSubsystemContext(
        station, simulator.get_mutable_context())
    station.GetInputPort("iiwa_position").FixValue(
        station_context, station.GetIiwaPosition(station_context))
    station.GetInputPort("iiwa_feedforward_torque").FixValue(
        station_context, np.zeros(7))
    station.GetInputPort("wsg_position").FixValue(
        station_context, np.zeros(1))
    station.GetInputPort("wsg_force_limit").FixValue(
        station_context, [40.0])
    simulator.AdvanceTo(args.duration)
Exemplo n.º 12
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def main():
    parser = argparse.ArgumentParser(description=__doc__)
    parser.add_argument(
        "--target_realtime_rate", type=float, default=1.0,
        help="Desired rate relative to real time.  See documentation for "
             "Simulator::set_target_realtime_rate() for details.")
    parser.add_argument(
        "--duration", type=float, default=np.inf,
        help="Desired duration of the simulation in seconds.")
    parser.add_argument(
        "--hardware", action='store_true',
        help="Use the ManipulationStationHardwareInterface instead of an "
             "in-process simulation.")
    parser.add_argument(
        "--test", action='store_true',
        help="Disable opening the gui window for testing.")
    parser.add_argument(
        "--filter_time_const", type=float, default=0.1,
        help="Time constant for the first order low pass filter applied to"
             "the teleop commands")
    parser.add_argument(
        "--velocity_limit_factor", type=float, default=1.0,
        help="This value, typically between 0 and 1, further limits the "
             "iiwa14 joint velocities. It multiplies each of the seven "
             "pre-defined joint velocity limits. "
             "Note: The pre-defined velocity limits are specified by "
             "iiwa14_velocity_limits, found in this python file.")
    parser.add_argument(
        '--setup', type=str, default='manipulation_class',
        help="The manipulation station setup to simulate. ",
        choices=['manipulation_class', 'clutter_clearing', 'planar'])
    parser.add_argument(
        '--schunk_collision_model', type=str, default='box',
        help="The Schunk collision model to use for simulation. ",
        choices=['box', 'box_plus_fingertip_spheres'])
    MeshcatVisualizer.add_argparse_argument(parser)
    args = parser.parse_args()

    builder = DiagramBuilder()

    if args.hardware:
        station = builder.AddSystem(ManipulationStationHardwareInterface())
        station.Connect(wait_for_cameras=False)
    else:
        station = builder.AddSystem(ManipulationStation())

        if args.schunk_collision_model == "box":
            schunk_model = SchunkCollisionModel.kBox
        elif args.schunk_collision_model == "box_plus_fingertip_spheres":
            schunk_model = SchunkCollisionModel.kBoxPlusFingertipSpheres

        # Initializes the chosen station type.
        if args.setup == 'manipulation_class':
            station.SetupManipulationClassStation(
                schunk_model=schunk_model)
            station.AddManipulandFromFile(
                "drake/examples/manipulation_station/models/"
                + "061_foam_brick.sdf",
                RigidTransform(RotationMatrix.Identity(), [0.6, 0, 0]))
        elif args.setup == 'clutter_clearing':
            station.SetupClutterClearingStation(
                schunk_model=schunk_model)
            ycb_objects = CreateClutterClearingYcbObjectList()
            for model_file, X_WObject in ycb_objects:
                station.AddManipulandFromFile(model_file, X_WObject)
        elif args.setup == 'planar':
            station.SetupPlanarIiwaStation(
                schunk_model=schunk_model)
            station.AddManipulandFromFile(
                "drake/examples/manipulation_station/models/"
                + "061_foam_brick.sdf",
                RigidTransform(RotationMatrix.Identity(), [0.6, 0, 0]))

        station.Finalize()

        # If using meshcat, don't render the cameras, since RgbdCamera
        # rendering only works with drake-visualizer. Without this check,
        # running this code in a docker container produces libGL errors.
        if args.meshcat:
            meshcat = ConnectMeshcatVisualizer(
                builder, output_port=station.GetOutputPort("geometry_query"),
                zmq_url=args.meshcat, open_browser=args.open_browser)
            if args.setup == 'planar':
                meshcat.set_planar_viewpoint()

        elif args.setup == 'planar':
            pyplot_visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(
                station.get_scene_graph()))
            builder.Connect(station.GetOutputPort("pose_bundle"),
                            pyplot_visualizer.get_input_port(0))
        else:
            DrakeVisualizer.AddToBuilder(builder,
                                         station.GetOutputPort("query_object"))
            image_to_lcm_image_array = builder.AddSystem(
                ImageToLcmImageArrayT())
            image_to_lcm_image_array.set_name("converter")
            for name in station.get_camera_names():
                cam_port = (
                    image_to_lcm_image_array
                    .DeclareImageInputPort[PixelType.kRgba8U](
                        "camera_" + name))
                builder.Connect(
                    station.GetOutputPort("camera_" + name + "_rgb_image"),
                    cam_port)

            image_array_lcm_publisher = builder.AddSystem(
                LcmPublisherSystem.Make(
                    channel="DRAKE_RGBD_CAMERA_IMAGES",
                    lcm_type=image_array_t,
                    lcm=None,
                    publish_period=0.1,
                    use_cpp_serializer=True))
            image_array_lcm_publisher.set_name("rgbd_publisher")
            builder.Connect(
                image_to_lcm_image_array.image_array_t_msg_output_port(),
                image_array_lcm_publisher.get_input_port(0))

    robot = station.get_controller_plant()
    params = DifferentialInverseKinematicsParameters(robot.num_positions(),
                                                     robot.num_velocities())

    time_step = 0.005
    params.set_timestep(time_step)
    # True velocity limits for the IIWA14 (in rad, rounded down to the first
    # decimal)
    iiwa14_velocity_limits = np.array([1.4, 1.4, 1.7, 1.3, 2.2, 2.3, 2.3])
    if args.setup == 'planar':
        # Extract the 3 joints that are not welded in the planar version.
        iiwa14_velocity_limits = iiwa14_velocity_limits[1:6:2]
        # The below constant is in body frame.
        params.set_end_effector_velocity_gain([1, 0, 0, 0, 1, 1])
    # Stay within a small fraction of those limits for this teleop demo.
    factor = args.velocity_limit_factor
    params.set_joint_velocity_limits((-factor*iiwa14_velocity_limits,
                                      factor*iiwa14_velocity_limits))
    differential_ik = builder.AddSystem(DifferentialIK(
        robot, robot.GetFrameByName("iiwa_link_7"), params, time_step))

    builder.Connect(differential_ik.GetOutputPort("joint_position_desired"),
                    station.GetInputPort("iiwa_position"))

    teleop = builder.AddSystem(EndEffectorTeleop(args.setup == 'planar'))
    if args.test:
        teleop.window.withdraw()  # Don't display the window when testing.
    filter = builder.AddSystem(
        FirstOrderLowPassFilter(time_constant=args.filter_time_const, size=6))

    builder.Connect(teleop.get_output_port(0), filter.get_input_port(0))
    builder.Connect(filter.get_output_port(0),
                    differential_ik.GetInputPort("rpy_xyz_desired"))

    wsg_buttons = builder.AddSystem(SchunkWsgButtons(teleop.window))
    builder.Connect(wsg_buttons.GetOutputPort("position"),
                    station.GetInputPort("wsg_position"))
    builder.Connect(wsg_buttons.GetOutputPort("force_limit"),
                    station.GetInputPort("wsg_force_limit"))

    # When in regression test mode, log our joint velocities to later check
    # that they were sufficiently quiet.
    num_iiwa_joints = station.num_iiwa_joints()
    if args.test:
        iiwa_velocities = builder.AddSystem(SignalLogger(num_iiwa_joints))
        builder.Connect(station.GetOutputPort("iiwa_velocity_estimated"),
                        iiwa_velocities.get_input_port(0))
    else:
        iiwa_velocities = None

    diagram = builder.Build()
    simulator = Simulator(diagram)

    # This is important to avoid duplicate publishes to the hardware interface:
    simulator.set_publish_every_time_step(False)

    station_context = diagram.GetMutableSubsystemContext(
        station, simulator.get_mutable_context())

    station.GetInputPort("iiwa_feedforward_torque").FixValue(
        station_context, np.zeros(num_iiwa_joints))

    # If the diagram is only the hardware interface, then we must advance it a
    # little bit so that first LCM messages get processed. A simulated plant is
    # already publishing correct positions even without advancing, and indeed
    # we must not advance a simulated plant until the sliders and filters have
    # been initialized to match the plant.
    if args.hardware:
        simulator.AdvanceTo(1e-6)

    q0 = station.GetOutputPort("iiwa_position_measured").Eval(
        station_context)
    differential_ik.parameters.set_nominal_joint_position(q0)

    teleop.SetPose(differential_ik.ForwardKinematics(q0))
    filter.set_initial_output_value(
        diagram.GetMutableSubsystemContext(
            filter, simulator.get_mutable_context()),
        teleop.get_output_port(0).Eval(diagram.GetMutableSubsystemContext(
            teleop, simulator.get_mutable_context())))
    differential_ik.SetPositions(diagram.GetMutableSubsystemContext(
        differential_ik, simulator.get_mutable_context()), q0)

    simulator.set_target_realtime_rate(args.target_realtime_rate)
    simulator.AdvanceTo(args.duration)

    # Ensure that our initialization logic was correct, by inspecting our
    # logged joint velocities.
    if args.test:
        for time, qdot in zip(iiwa_velocities.sample_times(),
                              iiwa_velocities.data().transpose()):
            # TODO(jwnimmer-tri) We should be able to do better than a 40
            # rad/sec limit, but that's the best we can enforce for now.
            if qdot.max() > 0.1:
                print(f"ERROR: large qdot {qdot} at time {time}")
                sys.exit(1)
Exemplo n.º 13
0
            RigidTransform(RotationMatrix.Identity(), [0.6, 0, 0]))

    station.Finalize()

    ConnectDrakeVisualizer(builder, station.get_scene_graph(),
                           station.GetOutputPort("pose_bundle"))
    if args.meshcat:
        meshcat = builder.AddSystem(
            MeshcatVisualizer(station.get_scene_graph(),
                              zmq_url=args.meshcat,
                              open_browser=args.open_browser))
        builder.Connect(station.GetOutputPort("pose_bundle"),
                        meshcat.get_input_port(0))
    if args.setup == 'planar':
        pyplot_visualizer = builder.AddSystem(
            PlanarSceneGraphVisualizer(station.get_scene_graph()))
        builder.Connect(station.GetOutputPort("pose_bundle"),
                        pyplot_visualizer.get_input_port(0))

teleop = builder.AddSystem(
    JointSliders(station.get_controller_plant(), length=800))
if args.test:
    teleop.window.withdraw()  # Don't display the window when testing.

filter = builder.AddSystem(
    FirstOrderLowPassFilter(time_constant=2.0, size=station.num_iiwa_joints()))
builder.Connect(teleop.get_output_port(0), filter.get_input_port(0))
builder.Connect(filter.get_output_port(0),
                station.GetInputPort("iiwa_position"))

wsg_buttons = builder.AddSystem(SchunkWsgButtons(teleop.window))
Exemplo n.º 14
0
from pydrake.multibody.plant import AddMultibodyPlantSceneGraph
from pydrake.systems.analysis import Simulator
from pydrake.systems.framework import DiagramBuilder
from pydrake.systems.primitives import ConstantVectorSource
from pydrake.systems.planar_scenegraph_visualizer import (
    PlanarSceneGraphVisualizer)

builder = DiagramBuilder()
plant, scene_graph = AddMultibodyPlantSceneGraph(builder, time_step=0.0)

Parser(plant, scene_graph).AddModelFromFile(
    FindResourceOrThrow(
        "drake/manipulation/models/iiwa_description/urdf/planar_iiwa14_spheres_dense_elbow_collision.urdf"
    ))  # noqa
plant.Finalize()

visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(scene_graph))
builder.Connect(scene_graph.get_pose_bundle_output_port(),
                visualizer.get_input_port(0))

torque_command = builder.AddSystem(ConstantVectorSource(np.zeros(3)))
builder.Connect(torque_command.get_output_port(0),
                plant.get_actuation_input_port())

diagram = builder.Build()

simulator = Simulator(diagram)
simulator.set_target_realtime_rate(1.0)

simulator.AdvanceTo(1)
Exemplo n.º 15
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def main():
    args_parser = argparse.ArgumentParser(
        description=__doc__,
        formatter_class=argparse.RawDescriptionHelpFormatter)
    args_parser.add_argument("filename",
                             type=str,
                             help="Path to an SDF or URDF file.")
    args_parser.add_argument(
        "--package_path",
        type=str,
        default=None,
        help="Full path to the root package for reading in SDF resources.")
    args_parser.add_argument("--pyplot",
                             action="store_true",
                             help="Opens a pyplot figure for rendering using "
                             "PlanarSceneGraphVisualizer.")
    # TODO(russt): Consider supporting the PlanarSceneGraphVisualizer
    #  options as additional arguments.
    position_group = args_parser.add_mutually_exclusive_group()
    position_group.add_argument(
        "--position",
        type=float,
        nargs="+",
        default=[],
        help="A list of positions which must be the same length as the number "
        "of positions in the sdf model.  Note that most models have a "
        "floating-base joint by default (unless the sdf explicitly welds "
        "the base to the world, and so have 7 positions corresponding to "
        "the quaternion representation of that floating-base position.")
    position_group.add_argument(
        "--joint_position",
        type=float,
        nargs="+",
        default=[],
        help="A list of positions which must be the same length as the number "
        "of positions ASSOCIATED WITH JOINTS in the sdf model.  This "
        "does not include, e.g., floating-base coordinates, which will "
        "be assigned a default value.")
    args_parser.add_argument(
        "--test",
        action='store_true',
        help="Disable opening the gui window for testing.")
    args_parser.add_argument(
        "--visualize_collisions",
        action="store_true",
        help="Visualize the collision geometry in the visualizer. The "
        "collision geometries will be shown in red to differentiate "
        "them from the visual geometries.")
    # TODO(russt): Add option to weld the base to the world pending the
    # availability of GetUniqueBaseBody requested in #9747.
    MeshcatVisualizer.add_argparse_argument(args_parser)
    args = args_parser.parse_args()
    filename = args.filename
    if not os.path.isfile(filename):
        args_parser.error("File does not exist: {}".format(filename))

    builder = DiagramBuilder()
    scene_graph = builder.AddSystem(SceneGraph())

    # Construct a MultibodyPlant.
    plant = MultibodyPlant(0.0)
    plant.RegisterAsSourceForSceneGraph(scene_graph)

    # Create the parser.
    parser = Parser(plant)

    # Get the package pathname.
    if args.package_path:
        # Verify that package.xml is found in the designated path.
        package_path = os.path.abspath(args.package_path)
        if not os.path.isfile(os.path.join(package_path, "package.xml")):
            parser.error("package.xml not found at: {}".format(package_path))

        # Get the package map and populate it using the package path.
        package_map = parser.package_map()
        package_map.PopulateFromFolder(package_path)

    # Add the model from the file and finalize the plant.
    parser.AddModelFromFile(filename)

    # Find all the geometries that have not already been marked as
    # 'illustration' (visual) and assume they are collision geometries.
    # Then add illustration properties to them that will draw them in red
    # and fifty percent translucent.
    if args.visualize_collisions:
        source_id = plant.get_source_id()
        red_illustration = MakePhongIllustrationProperties([1, 0, 0, 0.5])
        for geometry_id in scene_graph.model_inspector().GetAllGeometryIds():
            if (scene_graph.model_inspector().GetIllustrationProperties(
                    geometry_id) is None):
                scene_graph.AssignRole(source_id, geometry_id,
                                       red_illustration)

    plant.Finalize()

    # Add sliders to set positions of the joints.
    sliders = builder.AddSystem(JointSliders(robot=plant))
    to_pose = builder.AddSystem(MultibodyPositionToGeometryPose(plant))
    builder.Connect(sliders.get_output_port(0), to_pose.get_input_port())
    builder.Connect(to_pose.get_output_port(),
                    scene_graph.get_source_pose_port(plant.get_source_id()))

    # Connect this to drake_visualizer.
    ConnectDrakeVisualizer(builder=builder, scene_graph=scene_graph)

    # Connect to Meshcat.
    if args.meshcat is not None:
        meshcat_viz = builder.AddSystem(
            MeshcatVisualizer(scene_graph, zmq_url=args.meshcat))
        builder.Connect(scene_graph.get_pose_bundle_output_port(),
                        meshcat_viz.get_input_port(0))

    if args.pyplot:
        pyplot = builder.AddSystem(PlanarSceneGraphVisualizer(scene_graph))
        builder.Connect(scene_graph.get_pose_bundle_output_port(),
                        pyplot.get_input_port(0))

    if len(args.position):
        sliders.set_position(args.position)
    elif len(args.joint_position):
        sliders.set_joint_position(args.joint_position)

    # Make the diagram and run it.
    diagram = builder.Build()
    simulator = Simulator(diagram)

    simulator.set_publish_every_time_step(False)

    if args.test:
        sliders.window.withdraw()
        simulator.AdvanceTo(0.1)
    else:
        simulator.set_target_realtime_rate(1.0)
        simulator.AdvanceTo(np.inf)
Exemplo n.º 16
0
def main():
    parser = argparse.ArgumentParser(description=__doc__)
    parser.add_argument(
        "--target_realtime_rate", type=float, default=1.0,
        help="Desired rate relative to real time.  See documentation for "
             "Simulator::set_target_realtime_rate() for details.")
    parser.add_argument(
        "--duration", type=float, default=np.inf,
        help="Desired duration of the simulation in seconds.")
    parser.add_argument(
        "--hardware", action='store_true',
        help="Use the ManipulationStationHardwareInterface instead of an "
             "in-process simulation.")
    parser.add_argument(
        "--test", action='store_true',
        help="Disable opening the gui window for testing.")
    parser.add_argument(
        '--setup', type=str, default='manipulation_class',
        help="The manipulation station setup to simulate. ",
        choices=['manipulation_class', 'clutter_clearing', 'planar'])
    MeshcatVisualizer.add_argparse_argument(parser)
    args = parser.parse_args()

    builder = DiagramBuilder()

    if args.hardware:
        # TODO(russt): Replace this hard-coded camera serial number with a
        # config file.
        camera_ids = ["805212060544"]
        station = builder.AddSystem(ManipulationStationHardwareInterface(
            camera_ids))
        station.Connect(wait_for_cameras=False)
    else:
        station = builder.AddSystem(ManipulationStation())

        # Initializes the chosen station type.
        if args.setup == 'manipulation_class':
            station.SetupManipulationClassStation()
            station.AddManipulandFromFile(
                "drake/examples/manipulation_station/models/"
                + "061_foam_brick.sdf",
                RigidTransform(RotationMatrix.Identity(), [0.6, 0, 0]))
        elif args.setup == 'clutter_clearing':
            station.SetupClutterClearingStation()
            ycb_objects = CreateClutterClearingYcbObjectList()
            for model_file, X_WObject in ycb_objects:
                station.AddManipulandFromFile(model_file, X_WObject)
        elif args.setup == 'planar':
            station.SetupPlanarIiwaStation()
            station.AddManipulandFromFile(
                "drake/examples/manipulation_station/models/"
                + "061_foam_brick.sdf",
                RigidTransform(RotationMatrix.Identity(), [0.6, 0, 0]))

        station.Finalize()

        ConnectDrakeVisualizer(builder, station.get_scene_graph(),
                               station.GetOutputPort("pose_bundle"))
        if args.meshcat:
            meshcat = builder.AddSystem(MeshcatVisualizer(
                    station.get_scene_graph(), zmq_url=args.meshcat,
                    open_browser=args.open_browser))
            builder.Connect(station.GetOutputPort("pose_bundle"),
                            meshcat.get_input_port(0))
        if args.setup == 'planar':
            pyplot_visualizer = builder.AddSystem(PlanarSceneGraphVisualizer(
                station.get_scene_graph()))
            builder.Connect(station.GetOutputPort("pose_bundle"),
                            pyplot_visualizer.get_input_port(0))

    teleop = builder.AddSystem(JointSliders(station.get_controller_plant(),
                                            length=800))
    if args.test:
        teleop.window.withdraw()  # Don't display the window when testing.

    num_iiwa_joints = station.num_iiwa_joints()
    filter = builder.AddSystem(FirstOrderLowPassFilter(
        time_constant=2.0, size=num_iiwa_joints))
    builder.Connect(teleop.get_output_port(0), filter.get_input_port(0))
    builder.Connect(filter.get_output_port(0),
                    station.GetInputPort("iiwa_position"))

    wsg_buttons = builder.AddSystem(SchunkWsgButtons(teleop.window))
    builder.Connect(wsg_buttons.GetOutputPort("position"),
                    station.GetInputPort("wsg_position"))
    builder.Connect(wsg_buttons.GetOutputPort("force_limit"),
                    station.GetInputPort("wsg_force_limit"))

    # When in regression test mode, log our joint velocities to later check
    # that they were sufficiently quiet.
    if args.test:
        iiwa_velocities = builder.AddSystem(SignalLogger(num_iiwa_joints))
        builder.Connect(station.GetOutputPort("iiwa_velocity_estimated"),
                        iiwa_velocities.get_input_port(0))
    else:
        iiwa_velocities = None

    diagram = builder.Build()
    simulator = Simulator(diagram)

    # This is important to avoid duplicate publishes to the hardware interface:
    simulator.set_publish_every_time_step(False)

    station_context = diagram.GetMutableSubsystemContext(
        station, simulator.get_mutable_context())

    station.GetInputPort("iiwa_feedforward_torque").FixValue(
        station_context, np.zeros(num_iiwa_joints))

    # If the diagram is only the hardware interface, then we must advance it a
    # little bit so that first LCM messages get processed. A simulated plant is
    # already publishing correct positions even without advancing, and indeed
    # we must not advance a simulated plant until the sliders and filters have
    # been initialized to match the plant.
    if args.hardware:
        simulator.AdvanceTo(1e-6)

    # Eval the output port once to read the initial positions of the IIWA.
    q0 = station.GetOutputPort("iiwa_position_measured").Eval(
        station_context)
    teleop.set_position(q0)
    filter.set_initial_output_value(diagram.GetMutableSubsystemContext(
        filter, simulator.get_mutable_context()), q0)

    simulator.set_target_realtime_rate(args.target_realtime_rate)
    simulator.AdvanceTo(args.duration)

    # Ensure that our initialization logic was correct, by inspecting our
    # logged joint velocities.
    if args.test:
        for time, qdot in zip(iiwa_velocities.sample_times(),
                              iiwa_velocities.data().transpose()):
            # TODO(jwnimmer-tri) We should be able to do better than a 40
            # rad/sec limit, but that's the best we can enforce for now.
            if qdot.max() > 0.1:
                print(f"ERROR: large qdot {qdot} at time {time}")
                sys.exit(1)