Example #1
0
    def __init__(self, dcm, mem, event, file_name):
        """
        @dcm                    : proxy to DCM (object)
        @mem                    : proxy to Motion (object)
        @event                  : event object (object)
        @file_name              : file to save log (string)
        """

        threading.Thread.__init__(self)
        self._event = event
        self._file_name = file_name

        self._robot_on_charging_station = subdevice.ChargingStationSensor(
            dcm, mem)
        self._battery_current_sensor = subdevice.BatteryChargeSensor(dcm, mem)
        self._wheelb_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelB")
        self._wheelfr_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelFR")
        self._wheelfl_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelFL")
        self._wheelb_speed_sen = subdevice.WheelSpeedSensor(dcm, mem, "WheelB")
        self._wheelfr_speed_sen = subdevice.WheelSpeedSensor(
            dcm, mem, "WheelFR")
        self._wheelfl_speed_sen = subdevice.WheelSpeedSensor(
            dcm, mem, "WheelFL")
        self._wheelb_stiffness = subdevice.WheelStiffnessActuator(
            dcm, mem, "WheelB")
        self._wheelfr_stiffness = subdevice.WheelStiffnessActuator(
            dcm, mem, "WheelFR")
        self._wheelfl_stiffness = subdevice.WheelStiffnessActuator(
            dcm, mem, "WheelFL")

        self._end = False
    def __init__(self, dcm, mem, event, file_name):
        """
        @dcm                    : proxy to DCM (object)
        @mem                    : proxy to ALMemory (object)
        @event                  : event (object)
        @file_name              : name of log file (string)
        """

        threading.Thread.__init__(self)
        self._mem = mem
        self._event = event
        self._file_name = file_name

        self._wheelb_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelB")
        self._wheelfr_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelFR")
        self._wheelfl_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelFL")
        self._wheelb_speed_sen = subdevice.WheelSpeedSensor(
            dcm, mem, "WheelB")
        self._wheelfr_speed_sen = subdevice.WheelSpeedSensor(
            dcm, mem, "WheelFR")
        self._wheelfl_speed_sen = subdevice.WheelSpeedSensor(
            dcm, mem, "WheelFL")

        self._end = False
def test_reliability_003(dcm, mem, motion, motion_wake_up, parameters,
                         direction):
    """
    Test : bumper detects step.
    Return True if bumper detects obstacles and robot stops
    Return False if bumper detects obstacle but robot moves again

    @dcm                : proxy to DCM (object)
    @mem                : proxy to ALMemory (object)
    @motion             : proxy to ALMotion (object)
    @motion_wake_up     : robot does it wakeUp
    @parameters         : dictionnary {"parameter":value} from config file
                            (dictionnary)
    @directions         : dictionnary {"direction":value} (dictionnary)
    """
    # Objects creation
    right_bumper = subdevice.Bumper(dcm, mem, "FrontRight")
    left_bumper = subdevice.Bumper(dcm, mem, "FrontLeft")
    back_bumper = subdevice.Bumper(dcm, mem, "Back")
    wheelfr_speed_act = subdevice.WheelSpeedActuator(dcm, mem, "WheelFR")
    wheelfl_speed_act = subdevice.WheelSpeedActuator(dcm, mem, "WheelFL")

    log = Log(dcm, mem, direction + "-" + parameters["Speed"][0])
    log.start()

    print "Go move"
    move(
        motion, float(parameters["Speed"][0]),
        qha_tools.read_section("reliability_003.cfg", "Direction" + direction))
    print "Move finish"

    flag = 0
    while flag < int(parameters["Nbcycles"][0]):
        if right_bumper.value or left_bumper.value or back_bumper.value:
            print "Bumper"
            time.sleep(3)  # Time to wait wheel actuators reaction...
            if wheelfr_speed_act.value == 0 and wheelfl_speed_act.value == 0:
                print "Stop OK"
                flag += 1
                time.sleep(5)  # Robot forget mapping
                moveto(
                    motion, float(parameters["MoveBackDistance"][0]),
                    qha_tools.read_section("reliability_003.cfg",
                                           "Direction" + direction))
                print "Move back OK"
                time.sleep(2)
                move(
                    motion, float(parameters["Speed"][0]),
                    qha_tools.read_section("reliability_003.cfg",
                                           "Direction" + direction))
                print "Move"
            else:
                print flag
                break

    log.stop()

    assert flag == int(parameters["Nbcycles"][0])
Example #4
0
def move_robot(dcm, mem, wait_time, list_wheels_to_use):
    """
    Makes the robot move.
    - The robot uses for each sequence two wheels and lets
    the third one unstiffed.
    - The speed is the same for the 3 wheels.
    - It returns the wheels used for each sequence.
    """

    #---------------------------------------------------------#
    #-------------------- Object creations -------------------#
    #---------------------------------------------------------#

    # Wheel speed actuators
    wheel_fr_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelFR")
    wheel_fl_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelFL")
    wheel_b_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelB")

    # Same speed for the 3 wheels
    speed_fraction = 0.3
    speed = speed_fraction * wheel_fr_speed_actuator.maximum

    # To know which wheels are used for each sequence
    list_stiffed_wheels = []

    # Make the robot move according to the wheels to use
    #-------------------------- CASE 1 -------------------------#
    if list_wheels_to_use[0] == 1 and list_wheels_to_use[1] == 1:

        wheel_fr_speed_actuator.mqvalue = [(-speed, wait_time)]
        wheel_fl_speed_actuator.mqvalue = [(speed, wait_time)]

        list_stiffed_wheels.append('fr')
        list_stiffed_wheels.append('fl')

        return list_stiffed_wheels

    #-------------------------- CASE 2 -------------------------#
    if list_wheels_to_use[1] == 1 and list_wheels_to_use[2] == 1:

        wheel_fl_speed_actuator.mqvalue = [(-speed, wait_time)]
        wheel_b_speed_actuator.mqvalue = [(speed, wait_time)]

        list_stiffed_wheels.append('fl')
        list_stiffed_wheels.append('b')

        return list_stiffed_wheels

    #-------------------------- CASE 3 -------------------------#
    if list_wheels_to_use[2] == 1 and list_wheels_to_use[0] == 1:

        wheel_b_speed_actuator.mqvalue = [(-speed, wait_time)]
        wheel_fr_speed_actuator.mqvalue = [(speed, wait_time)]

        list_stiffed_wheels.append('b')
        list_stiffed_wheels.append('fr')

        return list_stiffed_wheels
Example #5
0
 def fin():
     wheel_fr_speed_actuator = subdevice.WheelSpeedActuator(
         dcm, mem, "WheelFR")
     wheel_fl_speed_actuator = subdevice.WheelSpeedActuator(
         dcm, mem, "WheelFL")
     wheel_b_speed_actuator = subdevice.WheelSpeedActuator(
         dcm, mem, "WheelB")
     wheel_fr_speed_actuator.qvalue = (0.0, 0)
     wheel_fl_speed_actuator.qvalue = (0.0, 0)
     wheel_b_speed_actuator.qvalue = (0.0, 0)
     print "Robot stopped"
     tools.wait(dcm, wait_time)
Example #6
0
def log_wheels_actu_sens(request, dcm, mem, system, log_period):
    """
    Log wheels' speeds [rad/s] every 0.5s
    """
    wheel_fr_speed_sensor = subdevice.WheelSpeedSensor(dcm, mem, "WheelFR")
    wheel_fl_speed_sensor = subdevice.WheelSpeedSensor(dcm, mem, "WheelFL")
    wheel_b_speed_sensor = subdevice.WheelSpeedSensor(dcm, mem, "WheelB")
    wheel_fr_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelFR")
    wheel_fl_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelFL")
    wheel_b_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelB")

    file_extension = "csv"
    robot_name = system.robotName()
    date = datetime.datetime.now().strftime("%Y-%m-%d_%H-%M-%S")
    log_type = "wheels_speeds"
    file_name = "-".join([robot_name, date, log_type])
    output = ".".join([file_name, file_extension])

    data = open(output, 'w')
    data.write("Time (s)" + "," + "wheel FR speed sensor [rad/s]" + "," +
               "wheel FR speed actuator [rad/s]" + "," +
               "wheel FL speed sensor [rad/s]" + "," +
               "wheel FL speed actuator [rad/s]" + "," +
               "Wheel B speed sensor [rad/s]" + "," +
               "Wheel B speed actuator [rad/s]" + "\n")

    threading_flag = threading.Event()

    def log(threading_flag):
        cpt = 1
        time_init = time.time()
        while not threading_flag.is_set():
            line = ""
            if float(format((time.time() - time_init),
                            '.1f')) == (cpt * log_period):
                cpt += 1
                line += str(float(format((time.time() - time_init),
                         '.1f'))) + "," + \
                        str(wheel_fr_speed_sensor.value) + "," + \
                        str(wheel_fr_speed_actuator.value) + "," + \
                        str(wheel_fl_speed_sensor.value) + "," + \
                        str(wheel_fl_speed_actuator.value) + "," + \
                        str(wheel_b_speed_sensor.value) + "," + \
                        str(wheel_b_speed_actuator.value) + "\n"
                data.write(line)
                data.flush()

    log_thread = threading.Thread(target=log, args=(threading_flag, ))
    log_thread.start()
Example #7
0
def test_wheels_dico(request, result_base_folder, dcm, mem):
    """
    Create the appropriate objects for each joint.
    It logs the informations into a dictionnary and save the data into a file
    after each wheel test.
    """
    wheel_speed_actuator = subdevice.WheelSpeedActuator(
        dcm, mem, request.param)
    wheel_speed_sensor = subdevice.WheelSpeedSensor(dcm, mem, request.param)
    logger = qha_tools.Logger()

    def fin():
        """Method executed after a joint test."""
        result_file_path = "/".join([
            result_base_folder, wheel_speed_actuator.subdevice_type, "_".join(
                [wheel_speed_actuator.short_name,
                 str(logger.flag)])
        ]) + ".csv"
        logger.log_file_write(result_file_path)

    request.addfinalizer(fin)
    # creating a dictionnary with all the objects
    dico_object = {
        "wheelActuator": wheel_speed_actuator,
        "wheelSensor": wheel_speed_sensor,
        "logger": logger
    }
    return dico_object
def test_sensors_safety_001(robot_ip, dcm, mem, motion, session,
                            motion_wake_up, direction, speed):
    """
    Docstring
    """
    expected = {"ALMotion/MoveFailed": 1}
    module_name = "EventChecker_{}_".format(uuid.uuid4())
    obstacledetected = EventModule(mem)
    module_id = session.registerService(module_name, obstacledetected)
    obstacledetected.subscribe(module_name, expected)

    # Objects creation
    wheelb_speed_act = subdevice.WheelSpeedActuator(dcm, mem, "WheelB")
    wheelfr_speed_act = subdevice.WheelSpeedActuator(dcm, mem, "WheelFR")
    wheelfl_speed_act = subdevice.WheelSpeedActuator(dcm, mem, "WheelFL")

    flag_test = True

    log = multi_logger.Logger(
        robot_ip,
        "multi_logger.cfg",
        0.1,
        "Direction" + direction + " - " + str(speed) + ".csv")
    log.log()

    # Movement
    move(motion, speed,
         qha_tools.read_section("safety_001.cfg", "Direction" + direction)
         )

    time.sleep(1)

    while not obstacledetected.flag:
        if wheelb_speed_act.value == 0 and \
                wheelfr_speed_act.value == 0 and \
                wheelfl_speed_act.value == 0:
            flag_test = False

    log.stop()

    session.unregisterService(module_id)

    assert flag_test
    def __init__(self, dcm, mem, file_name):
        """
        @dcm                    : proxy to DCM (object)
        @mem                    : proxy to ALMemory (object)
        @file_name              : name of log file (string)
        """

        threading.Thread.__init__(self)
        self._mem = mem
        self._file_name = file_name

        self._wheelb_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelB")
        self._wheelfr_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelFR")
        self._wheelfl_speed_act = subdevice.WheelSpeedActuator(
            dcm, mem, "WheelFL")
        self._rightbumper = subdevice.Bumper(dcm, mem, "FrontRight")
        self._leftbumper = subdevice.Bumper(dcm, mem, "FrontLeft")

        self._end = False
Example #10
0
def move_robot_random(dcm, mem, wait_time, min_fraction, max_fraction,
                      max_random):
    """
    Makes the robot move randomly.
    """

    #---------------------------------------------------------#
    #-------------------- Object creations -------------------#
    #---------------------------------------------------------#

    # Wheel speed actuators
    wheel_fr_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelFR")
    wheel_fl_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelFL")
    wheel_b_speed_actuator = subdevice.WheelSpeedActuator(dcm, mem, "WheelB")

    # Random speed
    speed_fraction_fr = float(
        format(random.uniform(min_fraction, max_fraction), '.1f'))
    speed_fraction_fl = float(
        format(random.uniform(min_fraction, max_fraction), '.1f'))
    speed_fraction_b = float(
        format(random.uniform(min_fraction, max_fraction), '.1f'))

    print type(speed_fraction_fr)
    print type(speed_fraction_fl)
    print type(speed_fraction_b)

    speed_fr = speed_fraction_fr * wheel_fr_speed_actuator.maximum
    speed_fl = speed_fraction_fl * wheel_fl_speed_actuator.maximum
    speed_b = speed_fraction_b * wheel_b_speed_actuator.maximum

    alea = int(random.uniform(0, 15))

    # Make the robot move randomly
    #-------------------------- CASE 1 -------------------------#
    if alea <= 5:
        timed_commands_fr = [(-speed_fr, wait_time)]
        timed_commands_fl = [(speed_fl, wait_time)]
        timed_commands_b = [(0.0, wait_time)]

        wheel_fr_speed_actuator.mqvalue = timed_commands_fr
        wheel_fl_speed_actuator.mqvalue = timed_commands_fl

        return [timed_commands_fr, timed_commands_fl, timed_commands_b]

    #-------------------------- CASE 2 -------------------------#
    if alea > 5 and alea <= 10:
        timed_commands_fl = [(-speed_fl, wait_time)]
        timed_commands_b = [(speed_b, wait_time)]
        timed_commands_fr = [(0.0, wait_time)]

        wheel_fl_speed_actuator.mqvalue = timed_commands_fl
        wheel_b_speed_actuator.mqvalue = timed_commands_b

        return [timed_commands_fr, timed_commands_fl, timed_commands_b]

    #-------------------------- CASE 3 -------------------------#
    if alea > 10 and alea <= 15:
        timed_commands_b = [(-speed_b, wait_time)]
        timed_commands_fr = [(speed_fr, wait_time)]
        timed_commands_fl = [(0.0, wait_time)]

        wheel_b_speed_actuator.mqvalue = timed_commands_b
        wheel_fr_speed_actuator.mqvalue = timed_commands_fr

        return [timed_commands_fr, timed_commands_fl, timed_commands_b]
Example #11
0
def test_move_random(dcm, mem, leds, expressiveness, wait_time,
                     wait_time_bumpers, min_fraction, max_fraction, max_random,
                     stop_robot, wake_up_pos_brakes_closed, stiff_robot_wheels,
                     unstiff_joints, log_wheels_speed, log_bumper_pressions):

    #---------------------------------------------------------#
    #-------------------- Object creations -------------------#
    #---------------------------------------------------------#

    #------------------------- Wheels ------------------------#

    list_wheel_speed_actuator = [
        subdevice.WheelSpeedActuator(dcm, mem, "WheelFR"),
        subdevice.WheelSpeedActuator(dcm, mem, "WheelFL"),
        subdevice.WheelSpeedActuator(dcm, mem, "WheelB")
    ]

    list_wheel_speed_sensor = [
        subdevice.WheelSpeedSensor(dcm, mem, "WheelFR"),
        subdevice.WheelSpeedSensor(dcm, mem, "WheelFL"),
        subdevice.WheelSpeedSensor(dcm, mem, "WheelB")
    ]

    list_wheel_stiffness_actuator = [
        subdevice.WheelStiffnessActuator(dcm, mem, "WheelFR"),
        subdevice.WheelStiffnessActuator(dcm, mem, "WheelFL"),
        subdevice.WheelStiffnessActuator(dcm, mem, "WheelB")
    ]

    list_wheel_temperature = [
        subdevice.WheelTemperatureSensor(dcm, mem, "WheelFR"),
        subdevice.WheelTemperatureSensor(dcm, mem, "WheelFL"),
        subdevice.WheelTemperatureSensor(dcm, mem, "WheelB")
    ]

    #------------------------- Bumpers -----------------------#

    list_bumper = [
        subdevice.Bumper(dcm, mem, "FrontRight"),
        subdevice.Bumper(dcm, mem, "FrontLeft"),
        subdevice.Bumper(dcm, mem, "Back")
    ]

    #-------------------------- Leds --------------------------#

    # Disable notifications (from disconnected tablet)
    expressiveness._setNotificationEnabled(False)

    # Switch off eyes and ears leds
    leds.off('FaceLeds')
    leds.off('EarLeds')

    # Switch on shoulder leds
    leds.createGroup("shoulder_group", SHOULDER_LEDS)
    leds.on("shoulder_group")

    # Bumpers activation detection
    parameters_bumpers = tools.read_section("config.cfg",
                                            "BumpersActivationsParameters")

    # Launch bumper counter (thread)
    bumper_detection = mobile_base_utils.BumpersCounting(
        dcm, mem, leds, wait_time_bumpers)
    bumper_detection.start()

    #---------------------------------------------------------#
    #--------------------- Initialization --------------------#
    #---------------------------------------------------------#
    flag_bumpers = False
    list_commands = move_robot_random(dcm, mem, wait_time, min_fraction,
                                      max_fraction, max_random)
    tools.wait(dcm, 2000)

    #---------------------------------------------------------#
    #----------------------- Main Loop -----------------------#
    #---------------------------------------------------------#
    while flag_bumpers == False:

        try:
            #-------------------- Wall event -------------------#
            if (list_bumper[0].value == 1) or \
               (list_bumper[1].value == 1) or \
               (list_bumper[2].value == 1):

                # Robot hit wall --> Stop it
                list_wheel_speed_actuator[0].qvalue = (0.0, 0)
                list_wheel_speed_actuator[1].qvalue = (0.0, 0)
                list_wheel_speed_actuator[2].qvalue = (0.0, 0)

                # Going back
                list_wheel_speed_actuator[0].qvalue = [
                    (-1) * list_commands[0][0][0], wait_time
                ]
                list_wheel_speed_actuator[1].qvalue = [
                    (-1) * list_commands[1][0][0], wait_time
                ]
                list_wheel_speed_actuator[2].qvalue = [
                    (-1) * list_commands[2][0][0], wait_time
                ]

                tools.wait(dcm, 4000)

                # random again
                list_commands = move_robot_random(dcm, mem, wait_time,
                                                  min_fraction, max_fraction,
                                                  max_random)

                #tools.wait(dcm, 2000)

            #--------------------- Check temperatures --------------------#
            check_wheel_temperatures(dcm, leds, list_wheel_temperature,
                                     list_wheel_speed_actuator,
                                     list_wheel_stiffness_actuator)

            #-------------------- Check test variables -------------------#
            if bumper_detection.bumpers_activations == \
                    int(parameters_bumpers["nb_bumper_activations"][0]):
                bumper_detection.stop()
                flag_bumpers = True

        # Exit test if user interrupt
        except KeyboardInterrupt:
            print "\n******* User interrupt - ending test *******"
            bumper_detection.stop()
            break
Example #12
0
    def run(self):
        """ Log """
        robot_on_charging_station = subdevice.ChargingStationSensor(
            self.dcm, self.mem)
        battery_current = subdevice.BatteryCurrentSensor(self.dcm, self.mem)

        back_bumper_sensor = subdevice.Bumper(self.dcm, self.mem, "Back")

        wheelfr_speed_actuator = subdevice.WheelSpeedActuator(
            self.dcm, self.mem, "WheelFR")
        wheelfl_speed_actuator = subdevice.WheelSpeedActuator(
            self.dcm, self.mem, "WheelFL")
        wheelfr_speed_sensor = subdevice.WheelSpeedSensor(
            self.dcm, self.mem, "WheelFR")
        wheelfl_speed_sensor = subdevice.WheelSpeedSensor(
            self.dcm, self.mem, "WheelFL")
        wheelfr_current_sensor = subdevice.WheelCurrentSensor(
            self.dcm, self.mem, "WheelFR")
        wheelfl_current_sensor = subdevice.WheelCurrentSensor(
            self.dcm, self.mem, "WheelFL")

        log_file = open(self.file_name, 'w')
        log_file.write(
            "Time,Detection,Current,BackBumper,WheelFRSpeedActuator," +
            "WheelFRSpeedSensor,WheelFRCurrent,WheelFLSpeedActuator," +
            "WheelFLSpeedSensor,WheelFLCurrent\n")

        plot_server = easy_plot_connection.Server()

        time_init = time.time()
        while not self._end_plot:
            elapsed_time = time.time() - time_init

            plot_server.add_point("Detection", elapsed_time,
                                  robot_on_charging_station.value)
            plot_server.add_point("Current", elapsed_time,
                                  battery_current.value)
            plot_server.add_point("BackBumper", elapsed_time,
                                  back_bumper_sensor.value)
            plot_server.add_point("WheelFRSpeedActuator", elapsed_time,
                                  wheelfr_speed_actuator.value)
            plot_server.add_point("WheelFRSpeedSensor", elapsed_time,
                                  wheelfr_speed_sensor.value)

            line_to_write = ",".join([
                str(elapsed_time),
                str(robot_on_charging_station.value),
                str(battery_current.value),
                str(back_bumper_sensor.value),
                str(wheelfr_speed_actuator.value),
                str(wheelfr_speed_sensor.value),
                str(wheelfr_current_sensor.value),
                str(wheelfl_speed_actuator.value),
                str(wheelfl_speed_sensor.value),
                str(wheelfl_current_sensor.value)
            ])
            line_to_write += "\n"
            log_file.write(line_to_write)
            log_file.flush()

            time.sleep(0.1)
Example #13
0
def test_move_random(motion, dcm, mem, leds, expressiveness, wait_time,
                     wait_time_bumpers, min_fraction, max_fraction, max_random,
                     stop_robot, wakeup_no_rotation, stiff_robot_wheels,
                     unstiff_joints, log_wheels_speed, log_bumper_pressions):

    #---------------------------------------------------------#
    #-------------------- Object creations -------------------#
    #---------------------------------------------------------#

    #------------------------- Wheels ------------------------#

    list_wheel_speed_actuator = [
        subdevice.WheelSpeedActuator(dcm, mem, "WheelFR"),
        subdevice.WheelSpeedActuator(dcm, mem, "WheelFL"),
        subdevice.WheelSpeedActuator(dcm, mem, "WheelB")
    ]

    list_wheel_speed_sensor = [
        subdevice.WheelSpeedSensor(dcm, mem, "WheelFR"),
        subdevice.WheelSpeedSensor(dcm, mem, "WheelFL"),
        subdevice.WheelSpeedSensor(dcm, mem, "WheelB")
    ]

    list_wheel_stiffness_actuator = [
        subdevice.WheelStiffnessActuator(dcm, mem, "WheelFR"),
        subdevice.WheelStiffnessActuator(dcm, mem, "WheelFL"),
        subdevice.WheelStiffnessActuator(dcm, mem, "WheelB")
    ]

    list_wheel_temperature = [
        subdevice.WheelTemperatureSensor(dcm, mem, "WheelFR"),
        subdevice.WheelTemperatureSensor(dcm, mem, "WheelFL"),
        subdevice.WheelTemperatureSensor(dcm, mem, "WheelB")
    ]

    #------------------------- Bumpers -----------------------#

    list_bumper = [
        subdevice.Bumper(dcm, mem, "FrontRight"),
        subdevice.Bumper(dcm, mem, "FrontLeft"),
        subdevice.Bumper(dcm, mem, "Back")
    ]

    #-------------------------- Leds --------------------------#

    # Disable notifications (from disconnected tablet)
    expressiveness._setNotificationEnabled(False)
    motion.setExternalCollisionProtectionEnabled('All', False)

    # Switch off eyes and ears leds
    leds.off('FaceLeds')
    leds.off('EarLeds')

    # Switch on shoulder leds
    leds.createGroup("shoulder_group", SHOULDER_LEDS)
    leds.on("shoulder_group")

    #----------------------------------------------------------#
    #--------------------- Test selection ---------------------#
    #----------------------------------------------------------#

    # Cables crossing detection
    parameters_cables = tools.read_section("config.cfg",
                                           "CablesRoutingParameters")

    # Bumpers activation detection
    parameters_bumpers = tools.read_section("config.cfg",
                                            "BumpersActivationsParameters")

    # Get the desired type of test
    flag_test = tools.read_section("config.cfg", "TestChoice")

    # Launch bumper counter (thread)
    if int(flag_test["test_bumpers"][0]) == 1:
        bumper_detection = mobile_base_utils.BumpersCounting(
            dcm, mem, leds, wait_time_bumpers)
        bumper_detection.start()

    # Launch cable counter (thread)
    if int(flag_test["test_cables_crossing"][0]) == 1:
        cable_detection = mobile_base_utils.CablesCrossing(dcm, mem)
        cable_detection.start()

    #---------------------------------------------------------#
    #--------------------- Initialization --------------------#
    #---------------------------------------------------------#
    flag_bumpers = False
    flag_cables = False
    list_wheels_to_use = [1, 1, 0]
    #tools.wait(dcm, 30000)
    used_wheels = move_robot(dcm, mem, wait_time, list_wheels_to_use)
    tools.wait(dcm, 2000)

    acc_z = subdevice.InertialSensorBase(dcm, mem, "AccelerometerZ")

    #---------------------------------------------------------#
    #----------------------- Main Loop -----------------------#
    #---------------------------------------------------------#
    while flag_bumpers == False and flag_cables == False:

        try:
            #-------------------- Wall event -------------------#
            if (math.fabs(list_wheel_speed_sensor[0].value) < 0.10) and \
               (math.fabs(list_wheel_speed_sensor[1].value) < 0.10) and \
               (math.fabs(list_wheel_speed_sensor[2].value) < 0.10):

                # Robot hit wall --> Stop it
                list_wheel_speed_actuator[0].qvalue = (0.0, 0)
                list_wheel_speed_actuator[1].qvalue = (0.0, 0)
                list_wheel_speed_actuator[2].qvalue = (0.0, 0)

                # stop_robot(list_wheel_speed_actuator)

                # check temperatures
                check_wheel_temperatures(dcm, leds, list_wheel_temperature,
                                         list_wheel_speed_actuator,
                                         list_wheel_stiffness_actuator)

                alea = int(random.uniform(0, 10))

                if used_wheels[0] == 'fr' and used_wheels[1] == 'fl':

                    wheel_stiffed_1 = list_wheel_stiffness_actuator[0]
                    wheel_stiffed_2 = list_wheel_stiffness_actuator[1]

                    list_wheel_stiffness_actuator[2].qvalue = (1.0, 0)

                    if alea <= 5:
                        wheel_stiffed_1.qvalue = (0.0, 0)
                        list_wheels_to_use = [0, 1, 1]
                    else:
                        wheel_stiffed_2.qvalue = (0.0, 0)
                        list_wheels_to_use = [1, 0, 1]

                if used_wheels[0] == 'fl' and used_wheels[1] == 'b':

                    wheel_stiffed_1 = list_wheel_stiffness_actuator[1]
                    wheel_stiffed_2 = list_wheel_stiffness_actuator[2]

                    list_wheel_stiffness_actuator[0].qvalue = (1.0, 0)

                    if alea <= 5:
                        wheel_stiffed_1.qvalue = (0.0, 0)
                        list_wheels_to_use = [1, 0, 1]
                    else:
                        wheel_stiffed_2.qvalue = (0.0, 0)
                        list_wheels_to_use = [1, 1, 0]

                if used_wheels[0] == 'b' and used_wheels[1] == 'fr':

                    wheel_stiffed_1 = list_wheel_stiffness_actuator[2]
                    wheel_stiffed_2 = list_wheel_stiffness_actuator[0]

                    list_wheel_stiffness_actuator[1].qvalue = (1.0, 0)

                    if alea <= 5:
                        wheel_stiffed_1.qvalue = (0.0, 0)
                        list_wheels_to_use = [1, 1, 0]
                    else:
                        wheel_stiffed_2.qvalue = (0.0, 0)
                        list_wheels_to_use = [0, 1, 1]

                used_wheels = move_robot(dcm, mem, wait_time,
                                         list_wheels_to_use)

                tools.wait(dcm, 2000)

            #-------------------- Check test variables -------------------#
            if int(flag_test["test_bumpers"][0]) == 1 and \
                    bumper_detection.bumpers_activations == \
                    int(parameters_bumpers["nb_bumper_activations"][0]):
                bumper_detection.stop()
                flag_bumpers = True

            if int(flag_test["test_cables_crossing"][0]) == 1 and \
                    cable_detection.cables_crossing == \
                    int(parameters_cables["Nb_cables_crossing"][0]):
                cable_detection.stop()
                flag_cables = True
            #-------- Robot has fallen ----------#
            if (math.fabs(acc_z.value)) < 2.0:

                if int(flag_test["test_bumpers"][0]) == 1:
                    bumper_detection.stop()

                if int(flag_test["test_cables_crossing"][0]) == 1:
                    cable_detection.stop()

                break

        # Exit test if user interrupt
        except KeyboardInterrupt:
            print "\n******* User interrupt - ending test *******"
            if int(flag_test["test_bumpers"][0]) == 1:
                bumper_detection.stop()
            if int(flag_test["test_cables_crossing"][0]) == 1:
                cable_detection.stop()
            break