Example #1
0
def main(args):
    success = False
    try:
        # Connect to V-REP
        print('Connecting to V-REP...')
        clientID = vu.connect_to_vrep()
        print('Connected.')

        # Reset simulation in case something was running
        vu.reset_sim(clientID)

        # Initial control inputs are zero
        vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

        # Despite the name, this sets the maximum allowable joint force
        vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

        # One step to process the above settings
        vu.step_sim(clientID)

        # Joint targets, radians for revolute joints and meters for prismatic joints
        gripper_targets = np.asarray([[-0.03, 0.03], [-0.03, 0.03]])
        joint_targets = np.radians([[-80, 0, 0, 0, 0], [0, 60, -75, -75, 0]])

        # Verify fk
        from utils import URDFRobot, print_pose
        robot = URDFRobot('urdf/locobot_description_v3.urdf')

        from forward_kinematics import ForwardKinematicsSolver
        fksolver = ForwardKinematicsSolver(robot)
        for target in joint_targets:
            print(target)
            pose = fksolver.getWristPose(target[:5], robot,
                                         vu.ARM_JOINT_NAMES[:5])
            print_pose(pose)

        # Instantiate controller and run it
        controller = ArmController(clientID)
        controller.execute(joint_targets, gripper_targets)
        success = True

    except Exception as e:
        print(e)
        traceback.print_exc()

    finally:
        # Stop VREP simulation
        vu.stop_sim(clientID)

    # Plot time histories
    if success: controller.plot()
def main(args):
    global link_cuboid_spec
    global obstacle_cuboid_spec

    # Connect to V-REP
    print('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print('Connected.')

    # Reset simulation in case something was running
    vu.reset_sim(clientID)

    # Initial control inputs are zero
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

    # Despite the name, this sets the maximum allowable joint force
    vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

    # One step to process the above settings
    vu.step_sim(clientID)

    deg_to_rad = np.pi / 180.

    link_cuboid_list = ("arm_base_link_joint_collision_cuboid",
                        "shoulder_link_collision_cuboid",
                        "elbow_link_collision_cuboid",
                        "forearm_link_collision_cuboid",
                        "wrist_link_collision_cuboid",
                        "gripper_link_collision_cuboid",
                        "finger_r_collision_cuboid",
                        "finger_l_collision_cuboid")
    for link_cuboid in link_cuboid_list:
        d = vu.get_handle_by_name(clientID, link_cuboid)
        link_spec = {}
        link_spec["Origin"] = vu.get_object_position(clientID, d)
        link_spec["Orientation"] = vu.get_object_orientation(clientID, d)
        link_spec["Dimension"] = vu.get_object_bounding_box(clientID, d)
        link_cuboid_spec.append(link_spec)

    obstacle_cuboid_list = ("cuboid_0", "cuboid_1", "cuboid_2", "cuboid_3",
                            "cuboid_4", "cuboid_5")
    for obstacle_cuboid in obstacle_cuboid_list:
        d = vu.get_handle_by_name(clientID, obstacle_cuboid)
        obstacle_spec = {}
        obstacle_spec["Origin"] = vu.get_object_position(clientID, d)
        obstacle_spec["Orientation"] = vu.get_object_orientation(clientID, d)
        obstacle_spec["Dimension"] = vu.get_object_bounding_box(clientID, d)
        obstacle_cuboid_spec.append(obstacle_spec)
    print("done")
def main(args):
    # Connect to V-REP
    print ('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print ('Connected.')

    # Reset simulation in case something was running
    vu.reset_sim(clientID)

    # Initial control inputs are zero
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

    # Despite the name, this sets the maximum allowable joint force
    vu.set_arm_joint_forces(clientID, 50.*np.ones(vu.N_ARM_JOINTS))

    # One step to process the above settings
    vu.step_sim(clientID)

    deg_to_rad = np.pi/180.

    # Joint targets. Specify in radians for revolute joints and meters for prismatic joints.
    # The order of the targets are as follows:
    #   joint_1 / revolute  / arm_base_link <- shoulder_link
    #   joint_2 / revolute  / shoulder_link <- elbow_link
    #   joint_3 / revolute  / elbow_link    <- forearm_link
    #   joint_4 / revolute  / forearm_link  <- wrist_link
    #   joint_5 / revolute  / wrist_link    <- gripper_link
    #   joint_6 / prismatic / gripper_link  <- finger_r
    #   joint_7 / prismatic / gripper_link  <- finger_l
    joint_targets = [[  0.,
                        0.,
                        0.,
                        0.,
                        0.,
                      - 0.07,
                        0.07], \
                     [-45.*deg_to_rad,
                      -15.*deg_to_rad,
                       20.*deg_to_rad,
                       15.*deg_to_rad,
                      -75.*deg_to_rad,
                      - 0.03,
                        0.03], \
                     [ 30.*deg_to_rad,
                       60.*deg_to_rad,
                      -65.*deg_to_rad,
                       45.*deg_to_rad,
                        0.*deg_to_rad,
                      - 0.05,
                        0.05]]

    # Instantiate controller
    controller = ArmController()

    i=0

    # Iterate through target joint positions
    for target in joint_targets:

        # Set new target position
        controller.set_target_joint_positions(target)

        steady_state_reached = False
        while not steady_state_reached:
            i+=1

            timestamp = vu.get_sim_time_seconds(clientID)
            print('Simulation time: {} sec'.format(timestamp))

            # Get current joint positions
            sensed_joint_positions = vu.get_arm_joint_positions(clientID)

            # Calculate commands
            commands = controller.calculate_commands_from_feedback(timestamp, sensed_joint_positions)

            # Send commands to V-REP
            vu.set_arm_joint_target_velocities(clientID, commands)

            # Print current joint positions (comment out if you'd like)
            #print(sensed_joint_positions)
            vu.step_sim(clientID, 1)

            if(i==1):
                joint_pos = np.array(sensed_joint_positions)
                target_pos = np.array(target)
                time_history = np.array(timestamp)
            else:
                joint_pos = np.vstack((joint_pos,sensed_joint_positions))
                target_pos = np.vstack((target_pos,target))
                time_history = np.hstack((time_history,timestamp))

            # Determine if we've met the condition to move on to the next point
            steady_state_reached = controller.has_stably_converged_to_target()

    vu.stop_sim(clientID)

    plt.figure(1)

    plt.subplot(331)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Angle(rad)')
    plt.title('Joint 1 position over time')
    plt.plot(time_history,joint_pos[:,0],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,0],'-r',label='Target position')

    plt.subplot(332)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Angle(rad)')
    plt.title('Joint 2 position over time')
    plt.plot(time_history,joint_pos[:,1],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,1],'-r',label='Target position')

    plt.subplot(333)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Angle(rad)')
    plt.title('Joint 3 position over time')
    plt.plot(time_history,joint_pos[:,2],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,2],'-r',label='Target position')

    plt.subplot(334)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Angle(rad)')
    plt.title('Joint 4 position over time')
    plt.plot(time_history,joint_pos[:,3],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,3],'-r',label='Target position')

    plt.subplot(335)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Angle(rad)')
    plt.title('Joint 5 position over time')
    plt.plot(time_history,joint_pos[:,4],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,4],'-r',label='Target position')

    plt.subplot(336)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Position(m)')
    plt.title('Joint 6 position over time')
    plt.plot(time_history,joint_pos[:,5],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,5],'-r',label='Target position')

    plt.subplot(337)
    plt.xlabel('Timestamp (s)')
    plt.ylabel('Position(m)')
    plt.title('Joint 7 position over time')
    plt.plot(time_history,joint_pos[:,6],'-b',label='Sensed position')
    plt.plot(time_history,target_pos[:,6],'-r',label='Target position')
    plt.show()
Example #4
0
def main(args):
    # Connect to V-REP
    print('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print('Connected.')

    # Reset simulation in case something was running
    vu.reset_sim(clientID)

    # Initial control inputs are zero
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

    # Despite the name, this sets the maximum allowable joint force
    vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

    # One step to process the above settings
    vu.step_sim(clientID)

    # Joint targets. Specify in radians for revolute joints and meters for prismatic joints.
    # The order of the targets are as follows:
    #   joint_1 / revolute  / arm_base_link <- shoulder_link
    #   joint_2 / revolute  / shoulder_link <- elbow_link
    #   joint_3 / revolute  / elbow_link    <- forearm_link
    #   joint_4 / revolute  / forearm_link  <- wrist_link
    #   joint_5 / revolute  / wrist_link    <- gripper_link
    #   joint_6 / prismatic / gripper_link  <- finger_r
    #   joint_7 / prismatic / gripper_link  <- finger_l
    joint_targets = [[0., 0., 0., 0., 0., -0.00, 0.00]]

    # Instantiate controller
    controller = ArmController()

    # Iterate through target joint positions
    for target in joint_targets:
        # Set new target position
        controller.set_target_joint_positions(target)

        steady_state_reached = False
        while not steady_state_reached:

            timestamp = vu.get_sim_time_seconds(clientID)
            print('Simulation time: {} sec'.format(timestamp))

            # Get current joint positions
            sensed_joint_positions = vu.get_arm_joint_positions(clientID)

            # Calculate commands
            commands = controller.calculate_commands_from_feedback(
                timestamp, sensed_joint_positions)

            # Send commands to V-REP
            vu.set_arm_joint_target_velocities(clientID, commands)

            # Print current joint positions (comment out if you'd like)
            print(sensed_joint_positions)
            vu.step_sim(clientID, 1)

            # Determine if we've met the condition to move on to the next point
            steady_state_reached = controller.has_stably_converged_to_target()

    vu.stop_sim(clientID)

    titles = [
        'Joint_1', 'Joint_2', 'Joint_3', 'Joint_4', 'Joint_5', 'Joint_6',
        'Joint_7'
    ]
    for i in range(7):
        plt.figure(i)
        #plt.subplot(4,2,i+1)
        plt.plot(np.asarray(controller.history['timestamp']),
                 np.asarray(controller.history['joint_feedback'])[:, i])
        plt.plot(np.asarray(controller.history['timestamp']),
                 np.asarray(controller.history['joint_target'])[:, i], 'r--')
        if (i < 5):
            plt.ylabel('Joint Angle')
        else:
            plt.ylabel('Joint Position')
        plt.xlabel('Time')
        plt.title(titles[i])
    plt.show()
Example #5
0
def main(args):
    # Connect to V-REP
    print('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print('Connected.')

    # Reset simulation in case something was running
    vu.reset_sim(clientID)

    # Initial control inputs are zero
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

    # Despite the name, this sets the maximum allowable joint force
    vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

    # One step to process the above settings
    vu.step_sim(clientID)

    deg_to_rad = np.pi / 180.

    # Joint targets. Specify in radians for revolute joints and meters for prismatic joints.
    # The order of the targets are as follows:
    #   joint_1 / revolute  / arm_base_link <- shoulder_link
    #   joint_2 / revolute  / shoulder_link <- elbow_link
    #   joint_3 / revolute  / elbow_link    <- forearm_link
    #   joint_4 / revolute  / forearm_link  <- wrist_link
    #   joint_5 / revolute  / wrist_link    <- gripper_link
    #   joint_6 / prismatic / gripper_link  <- finger_r
    #   joint_7 / prismatic / gripper_link  <- finger_l
    joint_targets = [[  0.,
                        0.,
                        0.,
                        0.,
                        0.,
                      - 0.07,
                        0.07], \
                     [-45.*deg_to_rad,
                      -15.*deg_to_rad,
                       20.*deg_to_rad,
                       15.*deg_to_rad,
                      -75.*deg_to_rad,
                      - 0.03,
                        0.03], \
                     [ 30.*deg_to_rad,
                       60.*deg_to_rad,
                      -65.*deg_to_rad,
                       45.*deg_to_rad,
                        0.*deg_to_rad,
                      - 0.05,
                        0.05]]

    # Instantiate controller
    controller = ArmController()

    # Iterate through target joint positions
    for target in joint_targets:

        # Set new target position
        controller.set_target_joint_positions(target)

        steady_state_reached = False
        while not steady_state_reached:

            timestamp = vu.get_sim_time_seconds(clientID)
            print('Simulation time: {} sec'.format(timestamp))

            # Get current joint positions
            sensed_joint_positions = vu.get_arm_joint_positions(clientID)

            # Calculate commands
            commands = controller.calculate_commands_from_feedback(
                timestamp, sensed_joint_positions)

            # Send commands to V-REP
            vu.set_arm_joint_target_velocities(clientID, commands)

            # Print current joint positions (comment out if you'd like)
            print(sensed_joint_positions)
            vu.step_sim(clientID, 1)

            # Determine if we've met the condition to move on to the next point
            steady_state_reached = controller.has_stably_converged_to_target()

    vu.stop_sim(clientID)
Example #6
0

def getArmCuboidDimension(orientation, dimension):
    volume = []
    for i in range(orientation.shape[0]):
        R = createRotationMatrix(orientation[i, :])
        volume.append(
            np.matmul(R.transpose(), dimension[i, :].transpose()).transpose())
    volume = np.stack(volume)
    return (volume)


if __name__ == "__main__":
    # Connect to V-REP
    print('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print('Connected.')

    vu.reset_sim(clientID)
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))
    vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

    deg_to_rad = np.pi / 180.

    controller = locobot_joint_ctrl.ArmController()

    obstacles = np.load('obstacles.npy')
    prm = PRM.PRM_Map(obstacles)
    start = np.array([[-80, 0, 0, 0, 0]])
    target = np.array([[0, 60, -75, -75, 0]])
    path = prm.Planner(start, target)
def main(args):
    # Connect to V-REP
    print('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print('Connected.')

    # Reset simulation in case something was running
    vu.reset_sim(clientID)

    # Initial control inputs are zero
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

    # Despite the name, this sets the maximum allowable joint force
    vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

    # One step to process the above settings
    vu.step_sim(clientID)

    deg_to_rad = np.pi / 180.

    link_cuboid_list = ("arm_base_link_joint_collision_cuboid",
                        "shoulder_link_collision_cuboid",
                        "elbow_link_collision_cuboid",
                        "forearm_link_collision_cuboid",
                        "wrist_link_collision_cuboid",
                        "gripper_link_collision_cuboid",
                        "finger_r_collision_cuboid",
                        "finger_l_collision_cuboid")
    for link_cuboid in link_cuboid_list:
        d = vu.get_handle_by_name(clientID, link_cuboid)
        link_spec = {}
        link_spec["Origin"] = vu.get_object_position(clientID, d)
        link_spec["Orientation"] = vu.get_object_orientation(clientID, d)
        link_spec["Dimension"] = vu.get_object_bounding_box(clientID, d)
        link_cuboid_spec.append(link_spec)

    obstacle_cuboid_list = ("cuboid_0", "cuboid_1", "cuboid_2", "cuboid_3",
                            "cuboid_4", "cuboid_5")
    for obstacle_cuboid in obstacle_cuboid_list:
        d = vu.get_handle_by_name(clientID, obstacle_cuboid)
        obstacle_spec = {}
        obstacle_spec["Origin"] = vu.get_object_position(clientID, d)
        obstacle_spec["Orientation"] = vu.get_object_orientation(clientID, d)
        obstacle_spec["Dimension"] = vu.get_object_bounding_box(clientID, d)
        obstacle_cuboid_spec.append(obstacle_spec)
    print("done")

    joint_targets = get_cuboid_config()

    # Instantiate controller
    controller = ArmController()

    # Iterate through target joint positions
    for target in joint_targets:

        # Set new target position
        controller.set_target_joint_positions(target)

        steady_state_reached = False
        while not steady_state_reached:
            timestamp = vu.get_sim_time_seconds(clientID)
            # print('Simulation time: {} sec'.format(timestamp))

            # Get current joint positions
            sensed_joint_positions = vu.get_arm_joint_positions(clientID)

            # Calculate commands
            commands = controller.calculate_commands_from_feedback(
                timestamp, sensed_joint_positions)

            # Send commands to V-REP
            vu.set_arm_joint_target_velocities(clientID, commands)

            # Print current joint positions (comment out if you'd like)
            vu.step_sim(clientID, 1)

            # Determine if we've met the condition to move on to the next point
            steady_state_reached = controller.has_stably_converged_to_target()

    vu.stop_sim(clientID)

    # Post simulation cleanup -- save results to a pickle, plot time histories, etc #####
    # Fill this out here (optional) or in your own script
    # If you use a separate script, don't forget to include it in the deliverables
    # ...
    #####################################################################################

    plt.figure()

    for i in range(7):
        plt.subplot(2, 4, i + 1)
        plt.title('Joint %d' % (i + 1))
        plt.xlabel('Time')
        plt.ylabel('Joint angle')
        a1 = np.array(controller.history['joint_feedback'])[:, i]
        a2 = np.array(controller.history['joint_target'])[:, i]
        plt.plot(0.05 * np.arange(len(a1)), a1)
        plt.plot(0.05 * np.arange(len(a2)), a2)
    plt.show()
def execute():
    # Connect to V-REP
    print('Connecting to V-REP...')
    clientID = vu.connect_to_vrep()
    print('Connected.')

    # Reset simulation in case something was running
    vu.reset_sim(clientID)

    # Initial control inputs are zero
    vu.set_arm_joint_target_velocities(clientID, np.zeros(vu.N_ARM_JOINTS))

    # Despite the name, this sets the maximum allowable joint force
    vu.set_arm_joint_forces(clientID, 50. * np.ones(vu.N_ARM_JOINTS))

    # One step to process the above settings
    vu.step_sim(clientID)

    deg_to_rad = np.pi / 180.

    # Joint targets. Specify in radians for revolute joints and meters for prismatic joints.
    # The order of the targets are as follows:
    #   joint_1 / revolute  / arm_base_link <- shoulder_link
    #   joint_2 / revolute  / shoulder_link <- elbow_link
    #   joint_3 / revolute  / elbow_link    <- forearm_link
    #   joint_4 / revolute  / forearm_link  <- wrist_link
    #   joint_5 / revolute  / wrist_link    <- gripper_link
    #   joint_6 / prismatic / gripper_link  <- finger_r
    #   joint_7 / prismatic / gripper_link  <- finger_l

    planned = np.load("execute_path.npy")
    res = []
    for plan in planned:
        res.append(plan.tolist())
    joint_targets = res

    # Instantiate controller
    controller = ArmController()

    # Iterate through target joint positions
    for i, target in enumerate(joint_targets):

        # Set new target position
        controller.set_target_joint_positions(target)

        steady_state_reached = False
        while not steady_state_reached:

            timestamp = vu.get_sim_time_seconds(clientID)
            #print('Simulation time: {} sec'.format(timestamp))

            # Get current joint positions
            sensed_joint_positions = vu.get_arm_joint_positions(clientID)

            # Calculate commands
            commands = controller.calculate_commands_from_feedback(
                timestamp, sensed_joint_positions)

            # Send commands to V-REP
            vu.set_arm_joint_target_velocities(clientID, commands)

            # Print current joint positions (comment out if you'd like)
            #print(sensed_joint_positions)
            vu.step_sim(clientID, 1)

            # Determine if we've met the condition to move on to the next point
            steady_state_reached = controller.has_stably_converged_to_target()

        #visualizer(clientID)
        #saveingCuboid(clientID,i)
        #savingJoints(clientID,i)
    vu.stop_sim(clientID)
    print "terminated"

    file = open('pickle_history', 'wb')
    pickle.dump(controller.history, file)
    file.close()