def __init__(self, filename):
        # Parsing the dwl control suite configuration and initialization
        self.parseConfigFile(filename)
        self.loop_sim = False
        self.fixed_base = False
        self.t = 0.

        # Creating the bullet clien and configure it
        if self.enable_gui:
            self.client = pb.connect(pb.GUI, options='--opengl2')
        else:
            self.client = pb.connect(pb.DIRECT)

        # Creating and configurating the bullet interface
        self.biface = BulletInterface(self.client)
        self.biface.setGravity(self.gravity[dwl.X],
                               self.gravity[dwl.Y],
                               self.gravity[dwl.Z])
        self.biface.setTimeStep(self.time_step)
        self.biface.resetDebugVisualizerCamera(self.cam_dist,
                                               self.cam_yaw,
                                               self.cam_pitch,
                                               self.cam_target.tolist())

        # Loading the ground model
        pb.setAdditionalSearchPath(pybullet_data.getDataPath())
        self.plane_id = pb.loadURDF('plane.urdf')

        # Loading the robot model to dwl and simulator
        self.fbs = dwl.FloatingBaseSystem()
        self.wkin = dwl.WholeBodyKinematics()
        self.wdyn = dwl.WholeBodyDynamics()
        self.fbs.resetFromURDFFile(self.root_path + self.urdf_path,
                                   self.root_path + self.yarf_path)
        self.wkin.reset(self.fbs)
        self.wdyn.reset(self.fbs, self.wkin)

        pb.setAdditionalSearchPath(self.root_path)
        self.robot_id = pb.loadURDF(self.urdf_path,
                                    self.robot_pos0.tolist(),
                                    pb.getQuaternionFromEuler(self.robot_rpy0),
                                    flags=pb.URDF_USE_INERTIA_FROM_FILE)

        # Creating the actual whole-body state
        self.ws_states = [dwl.WholeBodyState(self.fbs.getJointDoF()), # actual state
                          dwl.WholeBodyState(self.fbs.getJointDoF())] # desired state
    
        self.parseRobot()
        self.resetRobotPosition(self.robot_pos0)
        self.readControllerPlugins()

        # Creating the controller
        if not self.changeController(self.ctrl_name, self.ctrl_config):
            print bcolors.FAIL + 'Error: the default controller is not defined' + bcolors.ENDC
            sys.exit()

        if self.enable_ros:
            self.enableROS()
Beispiel #2
0
def extractWholeBodyControllerState(bagfile, topic):
    print('Extracting the WholeBodyControllerState message in topic' + topic +
          ' from rosbag ' + bagfile)

    n = 0
    initial_time = 0
    with rosbag.Bag(bagfile, 'r') as bag:
        initial_time = 0.
        duration = 0.
        starting_time = bag.get_start_time() + initial_time
        if (duration == 0.0):
            ending_time = bag.get_end_time()
            duration = ending_time - starting_time
        else:
            ending_time = starting_time + duration

        # Recording the whole-body state trajectory
        actual_ws_list = []
        desired_ws_list = []
        error_ws_list = []
        for (topic, msg, ts) in bag.read_messages(topics=str(topic)):
            # Recording the data in the desired time range
            if (ts.to_sec() >= starting_time and ts.to_sec() <= ending_time):
                # Getting the current time
                if (n == 0):
                    initial_time = ts.to_sec()
                time = ts.to_sec() - initial_time

                # Defined the desired, actual and error whole-body states
                actual_ws = dwl.WholeBodyState()
                desired_ws = dwl.WholeBodyState()
                error_ws = dwl.WholeBodyState()

                wbi = interface.WholeBodyStateInterface()
                wbi.writeFromMessage(actual_ws, msg.actual)
                wbi.writeFromMessage(desired_ws, msg.desired)
                wbi.writeFromMessage(error_ws, msg.error)

                # Defining our internal time rather than CPU time
                actual_ws.setTime(time)
                desired_ws.setTime(time)
                error_ws.setTime(time)

                # Appeding the whole-state to the list
                actual_ws_list.append(actual_ws)
                desired_ws_list.append(desired_ws)
                error_ws_list.append(error_ws)

                n += 1
    print('Loaded ' + str(n) +
          ' whole-body controller states from the bagfile.')

    return actual_ws_list, desired_ws_list, error_ws_list
Beispiel #3
0
def extractWholeBodyState(bagfile, topic, initial_time=0., duration=0.):
    print('Extracting the WholeBodyState message in topic' + topic +
          ' from rosbag ' + bagfile)

    n = 0
    with rosbag.Bag(bagfile, 'r') as bag:
        starting_time = bag.get_start_time() + initial_time
        if (duration == 0.):
            ending_time = bag.get_end_time()
            duration = ending_time - starting_time
        else:
            ending_time = starting_time + duration

        # Recording the whole-body state trajectory
        ws_list = []
        for (topic, msg, ts) in bag.read_messages(topics=str(topic)):
            # Recording the data in the desired time range
            if (ts.to_sec() >= starting_time and ts.to_sec() <= ending_time):
                # Getting the current time
                if (n == 0):
                    initial_time = ts.to_sec()
                time = ts.to_sec() - initial_time

                # Construct an instance of the WholeBodyState class, which wraps the C++ class.
                ws = dwl.WholeBodyState()

                wbi = interface.WholeBodyStateInterface()
                wbi.writeFromMessage(ws, msg)

                # Defining our internal time rather than CPU time
                ws.setTime(time)

                # Appeding the whole-state to the list
                ws_list.append(ws)

                n += 1
    print('Loaded ' + str(n) +
          ' whole-body controller states from the bagfile.')

    return ws_list
from __future__ import print_function
# This lets us use the python3-style print() function even in python2. It should have no effect if you're already running python3.

import os
import dwl
import numpy as np

# Configure the printing
np.set_printoptions(suppress=True)

# Construct an instance of the FloatingBaseSystem class, which wraps the C++ class.
fbs = dwl.FloatingBaseSystem()
ws = dwl.WholeBodyState()

# Initializing the URDF model and whole-body state
fpath = os.path.dirname(os.path.abspath(__file__))
fbs.resetFromURDFFile(fpath + "/../hyq.urdf", fpath + "/../../config/hyq.yarf")
ws.setJointDoF(fbs.getJointDoF())

# The robot state
ws.setBasePosition(np.array([0., 0., 0.]))
ws.setBaseRPY(np.array([0., 0., 0.]))
ws.setBaseVelocity_W(np.array([0., 0., 0.]))
ws.setBaseRPYVelocity_W(np.array([0., 0., 0.]))
ws.setBaseAcceleration_W(np.array([0., 0., 0.]))
ws.setBaseRPYAcceleration_W(np.array([0., 0., 0.]))
ws.setJointPosition(0.75, fbs.getJointId("lf_hfe_joint"))
ws.setJointPosition(-1.5, fbs.getJointId("lf_kfe_joint"))
ws.setJointPosition(-0.75, fbs.getJointId("lh_hfe_joint"))
ws.setJointPosition(1.5, fbs.getJointId("lh_kfe_joint"))
ws.setJointPosition(0.75, fbs.getJointId("rf_hfe_joint"))