Ejemplo n.º 1
0
def inputToPWM():

    # initialize node
    rospy.init_node('inputToPWM', anonymous=True)

    global pubname, newECU, subname, move, still_moving
    newECU = ECU()
    newECU.motor = 1500
    newECU.servo = 1550
    move = False
    still_moving = False
    #print("1")
    #print(move)
    # topic subscriptions / publications
    pubname = rospy.Publisher('ecu_pwm', ECU, queue_size=2)
    rospy.Subscriber('turtle1/cmd_vel', Twist, start_callback)
    rospy.Subscriber('encoder', Encoder, enc_callback)  # Line Added
    subname = rospy.Subscriber('uOpt', Input, callback_function)
    rospy.Subscriber('moving', Moving, moving_callback_function)
    # set node rate
    loop_rate = 40
    ts = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)
    t0 = time.time()

    while not rospy.is_shutdown():
        # calculate acceleration from PID controller.
        motor_pwm = PID_control.acc_calculate(v_ref, v_meas) + motor_pwm_offset
        # publish control command
        ecu_pub.publish(ECU(motor_pwm, servo_pwm))
        # wait
        rate.sleep()
Ejemplo n.º 2
0
def inputToPWM():
    
    # initialize node
    rospy.init_node('inputToPWM', anonymous=True)
    
    global pubname , newECU , subname, move , still_moving
    newECU = ECU() 
    newECU.motor = 1500
    newECU.servo = 1550
    move = False
    still_moving = False
    #print("1")
    #print(move)
    # topic subscriptions / publications
    pubname = rospy.Publisher('ecu_pwm',ECU, queue_size = 2)
    rospy.Subscriber('turtle1/cmd_vel', Twist, start_callback)
    subname = rospy.Subscriber('uOpt', Input, callback_function)
    rospy.Subscriber('moving', Moving, moving_callback_function)
    # set node rate
    loop_rate   = 40
    ts          = 1.0 / loop_rate
    rate        = rospy.Rate(loop_rate)
    t0          = time.time()
     
    rospy.spin()
Ejemplo n.º 3
0
def arduino_interface():
    global ecu_pub, motor_pwm, servo_pwm

    init_node('arduino_interface')
    # set node rate
    loop_rate = 50
    dt = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)

    time_prev = time.time()
    ecu_pub = Publisher('ecu_pwm', ECU, queue_size=10)

    while not rospy.is_shutdown():
        if time.time() >= time_prev and time.time() < time_prev + 6.5:
            motor_pwm = 1650
        if time.time() >= time_prev + 6.5:
            motor_pwm = 1500  #1465
            #if time.time() >= time_prev + 5 and time.time() < time_prev + 10:
            #   motor_pwm = 84.0
            #if time.time() >= time_prev + 12 and time.time() < time_prev + 17:
            #   motor_pwm = 86.0
            ecu_cmd = ECU(motor_pwm, servo_pwm)
            ecu_pub.publish(ecu_cmd)
            break

        ecu_cmd = ECU(motor_pwm, servo_pwm)
        ecu_pub.publish(ecu_cmd)

        # wait
        rate.sleep()
Ejemplo n.º 4
0
def arduino_interface():
    global ecu_pub, motor_pwm, servo_pwm

    init_node('arduino_interface')
    # set node rate
    loop_rate   = 50
    dt          = 1.0 / loop_rate
    rate        = rospy.Rate(loop_rate)
    
    time_prev = time.time()
    ecu_pub = Publisher('ecu_pwm', ECU, queue_size = 10)
    
    motor_pwm = 1600
    servo_pwm = 1400
    flag = 0

    while not rospy.is_shutdown():
#        if time.time()-time_prev>=3:
#            servo_pwm = 1540
        if time.time()-time_prev >= 8:
            motor_pwm = 1500
            ecu_cmd = ECU(motor_pwm, servo_pwm)
            ecu_pub.publish(ecu_cmd)
            break
	ecu_cmd = ECU(motor_pwm, servo_pwm)
        ecu_pub.publish(ecu_cmd)
	
        # wait
        rate.sleep()
Ejemplo n.º 5
0
def inputToPWM():
    global motor_pwm, servo_pwm, motor_pwm_offset, servo_pwm_offset
    global v_ref, v_meas

    # initialize node
    rospy.init_node('inputToPWM', anonymous=True)

    global pubname, newECU, subname, move, still_moving
    newECU = ECU()
    newECU.motor = 1500
    newECU.servo = 1550
    move = False
    still_moving = False
    #print("1")
    #print(move)
    # topic subscriptions / publications
    pubname = rospy.Publisher('ecu_pwm', ECU, queue_size=2)
    rospy.Subscriber('turtle1/cmd_vel', Twist, start_callback)
    subname = rospy.Subscriber('uOpt', Input, callback_function)
    rospy.Subscriber('moving', Moving, moving_callback_function)
    rospy.Subscriber('hold_previous_turn', Bool, hold_turn_function)
    rospy.Subscriber('encoder', Encoder, enc_callback)
    # set node rate
    loop_rate = 40
    ts = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)
    t0 = time.time()

    # Initialize the PID controller
    longitudinal_control = PID(kp=30, ki=3, kd=0)
    maxspeed = 1620
    minspeed = 1400

    while not rospy.is_shutdown():
        try:
            # acceleration calculated from PID controller
            motor_pwm = longitudinal_control.acc_calculate(
                v_ref, v_meas) + motor_pwm_offset
            if (motor_pwm < minspeed):
                motor_pwm = minspeed
            elif (motor_pwm > maxspeed):
                motor_pwm = maxspeed

            if (move == False):
                motor_pwm = 1500
                servo_pwm = 1550

            # publish information
            pubname.publish(ECU(motor_pwm, servo_pwm))

            # wait
            rate.sleep()
        except:
            pass
Ejemplo n.º 6
0
def move(current):
    msg = ECU()
    msg.motor = 1500
    msg.servo = 1500
    if 'a' in current:
        msg.servo -= 300
    elif 'd' in current:
        msg.servo += 300

    if 'w' in current:
        msg.motor += 100
    elif 's' in current:
        msg.motor -= 200

    return msg
Ejemplo n.º 7
0
def main_auto():
    # initialize ROS node
    init_node('auto_mode', anonymous=True)
    nh = Publisher('ecu', ECU, queue_size=10)

    # set node rate
    rateHz = get_param("controller/rate")
    rate = Rate(rateHz)
    dt = 1.0 / rateHz
    t_i = 0

    # get experiment parameters
    t_0 = get_param("controller/t_0")  # time to start test
    t_f = get_param("controller/t_f")  # time to end test
    FxR_target = get_param("controller/FxR_target")
    d_f_target = pi / 180 * get_param("controller/d_f_target")

    # main loop
    while not is_shutdown():
        # get command signal
        (FxR, d_f) = circular(t_i, t_0, t_f, d_f_target, FxR_target)

        # send command signal
        ecu_cmd = ECU(FxR, d_f)
        nh.publish(ecu_cmd)

        # wait
        t_i += dt
        rate.sleep()
Ejemplo n.º 8
0
def controller():

    # initialize node
    rospy.init_node('vehicle_simulator', anonymous=True)

    # topic subscriptions / publications
    rospy.Subscriber('state_vehicle_simulator', Z_DynBkMdl, measurements_callback)
    rospy.Subscriber('state_vehicle_error_frame_simulator', Z_DynBkMdlErrorFrame, measurements_error_frame_callback)

    state_pub   = rospy.Publisher('ecu', ECU, queue_size = 10)

    # set node rate
    loop_rate   = 50
    dt          = 1.0 / loop_rate
    rate        = rospy.Rate(loop_rate)
    t0          = time.time()

    # set initial conditions 
    d_f = 0
    acc = 0

    while not rospy.is_shutdown():

        # publish state estimate

        acc = (1 - v_x)
        d_f = 0.1*(0 - ey) + (0 - epsi)

        # publish information
        state_pub.publish( ECU(acc, d_f) )

        # wait
        rate.sleep()
Ejemplo n.º 9
0
def controller():
    global motor_pwm, servo_pwm, motor_pwm_offset
    global v_ref, v_meas
    
    # Initialize node:
    rospy.init_node('simulationGain', anonymous=True)

    # TODO: Add your necessary topic subscriptions / publications, depending on your preferred method of velocity estimation
    ecu_pub   = rospy.Publisher('ecu_pwm', ECU, queue_size = 10)

    # Set node rate
    loop_rate   = 50
    rate        = rospy.Rate(loop_rate)
    
    # TODO: Initialize your PID controller here, with your chosen PI gains
    PID_control = PID(kp = 1, ki = 1, kd = 0)
    
    while not rospy.is_shutdown():
        # calculate acceleration from PID controller.
        motor_pwm = PID_control.acc_calculate(v_ref, v_meas) + motor_pwm_offset
 
        # publish control command
        ecu_pub.publish( ECU(motor_pwm, servo_pwm) )

        # wait
        rate.sleep()
Ejemplo n.º 10
0
def arduino_interface():
    global ecu_pub, motor_pwm, servo_pwm

    init_node('arduino_interface')
    # set node rate
    loop_rate = 50
    dt = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)

    time_prev = time.time()
    ecu_pub = Publisher('ecu_pwm', ECU, queue_size=10)

    while not rospy.is_shutdown():
        if time.time() >= time_prev and time.time() < time_prev + 4:
            motor_pwm = 1580.0
        if time.time() >= time_prev + 4 and time.time() < time_prev + 6:
            motor_pwm = 1620.0
        if time.time() >= time_prev + 6 and time.time() < time_prev + 8:
            motor_pwm = 1600.0
        if time.time() >= time_prev + 8 and time.time() < time_prev + 10:
            motor_pwm = 1500.0
        if time.time() >= time_prev + 10:
            break

        ecu_cmd = ECU(motor_pwm, servo_pwm)
        ecu_pub.publish(ecu_cmd)

        # wait
        rate.sleep()
Ejemplo n.º 11
0
def controller():
    global motor_pwm, servo_pwm, motor_pwm_offset
    global v_ref, v_meas
    # initialize node:
    rospy.init_node('simulationGain', anonymous=True)

    # topic subscriptions / publications
    rospy.Subscriber('encoder', Encoder, enc_callback)

    ecu_pub   = rospy.Publisher('ecu_pwm', ECU, queue_size = 10)

    # set node rate
    loop_rate   = 50
    rate        = rospy.Rate(loop_rate)

    # Initialize the PID controller
    PID_control = PID(kp=200, ki=0, kd=0.0)

    while not rospy.is_shutdown():
        # acceleration calculated from PID controller.
        motor_pwm = PID_control.acc_calculate(v_ref, v_meas) + motor_pwm_offset
        rospy.logwarn("pwm = {}".format(motor_pwm))
        # publish information
        ecu_pub.publish( ECU(motor_pwm, servo_pwm) )

        # wait
        rate.sleep()
def controller():
    global motor_pwm, servo_pwm, motor_pwm_offset, servo_pwm_offset
    global v_ref, v_meas, t_start
    # initialize node
    rospy.init_node('CorneringStiffnessTest', anonymous=True)

    # topic subscriptions / publications
    rospy.Subscriber('encoder', Encoder, enc_callback)

    ecu_pub = rospy.Publisher('ecu_pwm', ECU, queue_size=10)

    # set node rate
    loop_rate = 50
    rate = rospy.Rate(loop_rate)

    # Initialize the PID controller
    PID_control = PID(kp=55.0, ki=20.0, kd=0.0)

    while not rospy.is_shutdown():
        # acceleration calculated from PID controller.
        motor_pwm = PID_control.acc_calculate(v_ref, v_meas) + motor_pwm_offset
        # rospy.logwarn("pwm = {}".format(motor_pwm))
        t_now = time.time()
        servo_pwm = 200 * np.sin(pi * (t_now - t_start)) + servo_pwm_offset
        rospy.logwarn("pwm = {}".format(servo_pwm))
        # publish information
        ecu_pub.publish(ECU(motor_pwm, servo_pwm))

        # wait
        rate.sleep()
Ejemplo n.º 13
0
def controller():
    global motor_pwm, servo_pwm, motor_pwm_offset, servo_pwm_offset
    global v_ref, v_meas
    global lateral_error, x_est, y_est
    # initialize node:
    rospy.init_node('lateral_control', anonymous=True)

    # topic subscriptions / publications
    rospy.Subscriber('encoder', Encoder, enc_callback)
    rospy.Subscriber('state_estimate', Z_KinBkMdl, state_callback)

    ecu_pub   = rospy.Publisher('ecu_pwm', ECU, queue_size = 10)

    # set node rate
    loop_rate   = 50
    rate        = rospy.Rate(loop_rate)

    # Initialize the PID controller
    longitudinal_control = PID(kp=200, ki=0, kd=0.0)
    lateral_control = PID(kp=50, ki=0, kd=0.0)

    while not rospy.is_shutdown():
        # acceleration calculated from PID controller.
        motor_pwm = longitudinal_control.acc_calculate(v_ref, v_meas) + motor_pwm_offset
        servo_pwm = lateral_control.acc_calculate(0, lateral_error) + servo_pwm_offset
        rospy.logwarn("pwm = {}".format(motor_pwm))
        # publish information
        ecu_pub.publish( ECU(motor_pwm, servo_pwm) )

        # wait
        rate.sleep()
Ejemplo n.º 14
0
def arduino_interface():
    global ecu_pub, motor_pwm, servo_pwm

    # initialize node
    init_node('arduino_interface')

    # setup publishers and subscribers
    loop_rate = 50
    dt = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)
    time_prev = time.time()

    ecu_pub = Publisher('ecu_pwm', ECU, queue_size=10)
    v_meas_pub = rospy.Publisher('v_meas', Float32, queue_size=10)

    rospy.Subscriber('encoder', Encoder, enc_callback)

    while not rospy.is_shutdown():
        if time.time() >= time_prev and time.time() < time_prev + 4:
            motor_pwm = 1650
        if time.time() >= time_prev + 4:
            motor_pwm = 1500

        ecu_cmd = ECU(motor_pwm, servo_pwm)
        ecu_pub.publish(ecu_cmd)
        v_meas_pub.publish(Float32(v_meas))

        # wait
        rate.sleep()
Ejemplo n.º 15
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def callback(uOptdata):
    pub = rospy.Publisher('ecu', ECU, queue_size=10)
    servo = (uOptdata.delta - 71.0977) / -0.0461
    #motor= 1550
    motor = 1550
    out = ECU(motor, servo)
    pub.publish(out)
def main_auto():
    # initialize ROS node
    rospy.init_node('auto_mode', anonymous=True)
    nh = rospy.Publisher('ecu', ECU, queue_size=10)
    steering_offset_subscriber = rospy.Subscriber("lane_offset", Float32,
                                                  offset_callback)

    # set node rate
    rateHz = 50
    rate = rospy.Rate(rateHz)

    # set start time
    t0 = time.time()

    # specify test and test options
    v_x_pwm_1 = rospy.get_param("steering_controller/v_x_pwm_1")
    v_x_pwm_2 = rospy.get_param("steering_controller/v_x_pwm_2")
    tf = rospy.get_param("steering_controller/tf")

    # Get Controller Parameters
    Kp = rospy.get_param("steering_controller/Kp")
    Kd = rospy.get_param("steering_controller/Kd")
    Ki = rospy.get_param("steering_controller/Ki")

    # main loop
    while not rospy.is_shutdown():
        # get command signal
        servoCMD, steering_angle = steering_command(rateHz, Kp, Kd, Ki)
        v_x_pwm = speed_command(t0, tf, v_x_pwm_1, v_x_pwm_2)
        # send command signal
        ecu_cmd = ECU(v_x_pwm, servoCMD)
        nh.publish(ecu_cmd)

        # wait
        rate.sleep()
Ejemplo n.º 17
0
def main_auto():
    global nh, v_x_curr, max_torque
    # initialize ROS node
    rospy.init_node('auto_mode', anonymous=True)
    nh = rospy.Publisher('ecu', ECU, queue_size = 10)
     
    steering_offset_subscriber = rospy.Subscriber("lane_offset", Float32, offset_callback)
    rospy.Subscriber('encoder', Encoder, enc_callback)
    
    #XXX:DATALOGGING
    torque_pub = rospy.Publisher('torque', Float32, queue_size = 10)
    steering_angle_pub = rospy.Publisher('steering_angle', Float32, queue_size = 10)
    speed_pub = rospy.Publisher('speed', Float32, queue_size = 10)

    # set node rate
    rateHz  = 50
    rate 	= rospy.Rate(rateHz)

    # Get Desired Speed
    speed_desired = rospy.get_param("speed_controller/speed_desired")
    max_torque = rospy.get_param("speed_controller/max_torque")

    # Get Speed Controller Parameters
    KpS = rospy.get_param("speed_controller/KpS")
    KdS = rospy.get_param("speed_controller/KdS")
    KiS = rospy.get_param('speed_controller/KiS')
    
    # Get Turning Controller Parameters
    Kp 	= rospy.get_param("speed_controller/Kp")
    Kd 	= rospy.get_param("speed_controller/Kd")
    Ki 	= rospy.get_param("speed_controller/Ki")

    # get test time
    tf = rospy.get_param('speed_controller/test_time')

    # set start time
    t0 = time.time()
    
    # main loop
    while not rospy.is_shutdown():
        # get speed command signal
        speedCMD = speed_command(speed_desired, rateHz, KpS, KdS, KiS)
        if ((time.time()-t0)>tf):
            speedCMD = 40

        # get steering command signal
        servoCMD, angle = steering_command(rateHz, Kp, Kd, Ki)
        
        # send command signal 
        ecu_cmd = ECU(speedCMD, servoCMD)
        nh.publish(ecu_cmd)

        #XXX:DATALOGGING
        torque_pub.publish(speedCMD)
        steering_angle_pub.publish(angle)
        speed_pub.publish(v_x_curr)
        
        # wait
        rate.sleep()
Ejemplo n.º 18
0
def controller():
    global motor_pwm, servo_pwm, motor_pwm_offset
    global v_ref, v_meas

    # Initialize node:
    rospy.init_node('simulationGain', anonymous=True)

    # topic subscriptions / publications
    rospy.Subscriber('encoder', Encoder, enc_callback)
    # TODO: Add your necessary topic subscriptions / publications, depending on your preferred method of velocity estimation
    ecu_pub = rospy.Publisher('ecu_pwm', ECU, queue_size=10)
    velarr_pub = rospy.Publisher('velarr', ECU, queue_size=10)

    # Set node rate
    loop_rate = 50
    rate = rospy.Rate(loop_rate)

    # TODO: Initialize your PID controller here, with your chosen PI gains
    PID_control = PID(kp=20, ki=5, kd=0)

    while not rospy.is_shutdown():
        #rospy.sleep(2)
        # calculate acceleration from PID controller.
        arr_vel.append(v_meas)
        arr_vel.pop(0)
        v_meas = sum(arr_vel) / len(arr_vel)

        motor_pwm = PID_control.acc_calculate(v_ref, v_meas) + motor_pwm_offset
        if motor_pwm > 1650:
            motor_pwm = 1650

        arr_pwm.append(motor_pwm)
        arr_pwm.pop(0)
        motor_pwm = sum(arr_pwm) / len(arr_pwm)

        # publish information

        # publish control command
        ecu_pub.publish(ECU(motor_pwm, servo_pwm))
        velarr_pub.publish(ECU(v_meas, motor_pwm))

        # wait
        rate.sleep()
Ejemplo n.º 19
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class low_level_control(object):
    motor_pwm = 90
    servo_pwm = 90
    str_ang_max = 35
    str_ang_min = -35
    ecu_pub = 0
    ecu_cmd = ECU()

    def pwm_converter_callback(self, msg):
        # translate from SI units in vehicle model
        # to pwm angle units (i.e. to send command signal to actuators)
        # convert desired steering angle to degrees, saturate based on input limits

        # Old servo control:
        # self.servo_pwm = 91.365 + 105.6*float(msg.servo)
        # New servo Control
        # if msg.servo < 0.0:         # right curve
        #     self.servo_pwm = 95.5 + 118.8*float(msg.servo)
        # elif msg.servo > 0.0:       # left curve
        #     self.servo_pwm = 90.8 + 78.9*float(msg.servo)
        self.servo_pwm = 90.0 + 89.0 * float(msg.servo)

        # compute motor command
        FxR = float(msg.motor)
        if FxR == 0:
            self.motor_pwm = 90.0
        elif FxR > 0:
            #self.motor_pwm = max(94,91 + 6.5*FxR)   # using writeMicroseconds() in Arduino
            self.motor_pwm = 91 + 6.5 * FxR  # using writeMicroseconds() in Arduino

            # self.motor_pwm = max(94,90.74 + 6.17*FxR)
            #self.motor_pwm = 90.74 + 6.17*FxR

            #self.motor_pwm = max(94,90.12 + 5.24*FxR)
            #self.motor_pwm = 90.12 + 5.24*FxR
            # Note: Barc doesn't move for u_pwm < 93
        else:  # motor break / slow down
            self.motor_pwm = 93.5 + 46.73 * FxR
            # self.motor_pwm = 98.65 + 67.11*FxR
            #self.motor = 69.95 + 68.49*FxR
        self.update_arduino()

    def neutralize(self):
        self.motor_pwm = 40  # slow down first
        self.servo_pwm = 90
        self.update_arduino()
        rospy.sleep(1)  # slow down for 1 sec
        self.motor_pwm = 90
        self.update_arduino()

    def update_arduino(self):
        self.ecu_cmd.header.stamp = get_rostime()
        self.ecu_cmd.motor = self.motor_pwm
        self.ecu_cmd.servo = self.servo_pwm
        self.ecu_pub.publish(self.ecu_cmd)
Ejemplo n.º 20
0
    def _publish_ecu(self):
        # assemble the message to publish
        # acceleration command from keyboard
        acc_cmd = motor

        # steering angle command from keyboard
        d_f_cmd = servo

        ecu_out = ECU(acc_cmd, d_f_cmd)

        self.pub.publish(ecu_out)
Ejemplo n.º 21
0
def main_auto():
    global nh, v_x_enc
    # initialize ROS node
    rospy.init_node('auto_mode', anonymous=True)
    rospy.on_shutdown(shutdown_func)
    nh = rospy.Publisher('ecu', ECU, queue_size=10)

    steering_offset_subscriber = rospy.Subscriber("lane_offset", Float32,
                                                  offset_callback)
    rospy.Subscriber('encoder', Encoder, enc_callback)
    rospy.Subscriber('cv_abort', Int32, cv_fail_callback)

    #XXX:DATALOGGING
    torque_pub = rospy.Publisher('torque', Float32, queue_size=10)
    steering_angle_pub = rospy.Publisher('steering_angle',
                                         Float32,
                                         queue_size=10)
    speed_pub = rospy.Publisher('speed', Float32, queue_size=10)

    # set node rate
    rateHz = 50
    rate = rospy.Rate(rateHz)

    # Get Desired Speed
    speed_desired = rospy.get_param("speed_controller/speed_desired")

    # Get Speed Controller Parameters
    KpS = rospy.get_param("speed_controller/KpS")
    KdS = rospy.get_param("speed_controller/KdS")
    KiS = rospy.get_param('speed_controller/KiS')

    # Get Turning Controller Parameters
    Kp = rospy.get_param("speed_controller/Kp")
    Kd = rospy.get_param("speed_controller/Kd")
    Ki = rospy.get_param("speed_controller/Ki")

    # main loop
    while not rospy.is_shutdown():
        # get command signal
        speedCMD = speed_command(speed_desired, rateHz, KpS, KdS, KiS)
        servoCMD, angle = steering_command(rateHz, Kp, Kd, Ki)
        # send command signal
        ecu_cmd = ECU(speedCMD, servoCMD)
        nh.publish(ecu_cmd)

        #XXX:DATALOGGING
        torque_pub.publish(speedCMD)
        steering_angle_pub.publish(angle)
        speed_pub.publish(v_x_enc)

        # wait
        rate.sleep()
Ejemplo n.º 22
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def main_auto():
    # initialize ROS node
    rospy.init_node('auto_mode', anonymous=True)
    nh = rospy.Publisher('ecu', ECU, queue_size=10)
    rospy.Subscriber('imu', TimeData, imu_callback)

    # set node rate
    rateHz = 50
    dt = 1.0 / rateHz
    rate = rospy.Rate(rateHz)
    t_i = 0

    # specify test and test options
    experiment_opt = {
        0: CircularTest,
        1: Straight,
        2: SineSweep,
        3: DoubleLaneChange,
        4: CoastDown
    }
    experiment_sel = rospy.get_param("controller/experiment_sel")
    v_x_pwm = rospy.get_param("controller/v_x_pwm")
    t_0 = rospy.get_param("controller/t_0")
    t_exp = rospy.get_param("controller/t_exp")
    str_ang = rospy.get_param("controller/steering_angle")
    test_mode = experiment_opt.get(experiment_sel)
    opt = TestSettings(SPD=v_x_pwm, turn=str_ang, dt=t_exp)
    opt.t_0 = t_0

    # use simple pid control to keep steering straight
    p = rospy.get_param("controller/p")
    i = rospy.get_param("controller/i")
    d = rospy.get_param("controller/d")
    pid = PID(P=p, I=i, D=d)

    # main loop
    while not rospy.is_shutdown():
        # get steering wheel command
        u = pid.update(err, dt)
        servoCMD = angle_2_servo(u)

        # get command signal
        (motorCMD, _) = test_mode(opt, rateHz, t_i)

        # send command signal
        ecu_cmd = ECU(motorCMD, servoCMD)
        nh.publish(ecu_cmd)

        # wait
        t_i += 1
        rate.sleep()
Ejemplo n.º 23
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    def __init__(self, namespace, plotter_params, visualizer_params):
        """Initialization
        Arguments:

        """

        plot_sim = visualizer_params.plot_sim
        plot_est = visualizer_params.plot_est
        plot_sensor = visualizer_params.plot_sensor
        plot_gps = visualizer_params.plot_gps

        plot_state = plotter_params.plot_state
        plot_score = plotter_params.plot_score
        plot_pred = plotter_params.plot_pred
        plot_ss = plotter_params.plot_ss

        if plot_sim:
            rospy.Subscriber(namespace + '/sim_states', States,
                             self.simState_callback)
        if plot_sensor:
            rospy.Subscriber(namespace + '/mea_states', States,
                             self.meaState_callback)
        if plot_est:
            rospy.Subscriber(namespace + '/est_states', States,
                             self.estState_callback)
        if plot_pred:
            rospy.Subscriber(namespace + '/pred_states', Prediction,
                             self.predState_callback)
        if plot_ss:
            rospy.Subscriber(namespace + '/sel_ss', Prediction,
                             self.SS_callback)
        if plot_gps:
            rospy.Subscriber(namespace + '/gps_pos', States, self.gps_callback)
        if plot_state:
            rospy.Subscriber(namespace + '/fsm_state', FSMState,
                             self.fsm_state_callback)
        if plot_score:
            rospy.Subscriber(namespace + '/strategy_scores', Scores,
                             self.scores_callback)

        rospy.Subscriber(namespace + '/ecu', ECU, self.ecu_callback)

        self.sim_states = States()
        self.mea_states = States()
        self.est_states = States()
        self.pred_states = Prediction()
        self.ss_states = Prediction()
        self.gps = States()
        self.input = ECU()
        self.fsm_state = 'Start'
        self.scores = [0, 0, 0]
Ejemplo n.º 24
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def image_node():
    global error
    error = 0

    param_names = [
        'lowerY', 'upperY', 'display_image', 'display_processed_image',
        'debug_info', 'publish_processed_image'
    ]
    params = {}
    for param in param_names:
        params[param] = rospy.get_param(param)
    print(params)

    rospy.init_node('Test_Imager')
    img_pub = rospy.Publisher('/processed_image', Image, queue_size=1)
    #params['img_pub'] = img_pub
    rospy.Subscriber('/image_raw/compressed', CompressedImage, image_process,
                     params)
    pub = rospy.Publisher('ecu_pwm', ECU, queue_size=10)
    rate = rospy.Rate(10)

    K = 400
    Ki = 20
    integral = 0
    while not rospy.is_shutdown():
        msg = ECU()

        #   if params['debug_info']:
        #      print(error)
        msg.motor = 1590
        msg.servo = 1500 + K * error  # Ki*integral
        pub.publish(msg)
        integral += (1 / 10) * error
        if integral > 20:
            integral = 20
        if integral < -20:
            integral = -20
        rate.sleep()
Ejemplo n.º 25
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    def callback_data(self, data):
        global ang_o
        global ang_n
        ang_o = self.angle
        # Do all computation from the incoming message to the output message here
        self.angle = data.angle
        self.displacement = data.horizontal_displacement

        if self.angle > 0:
            self.angle = self.angle - pi

        ang_ctrl = Kp_angle * (self.angle) + Kp_disp * (self.displacement)

        self.publisher.publish(ECU(6.5, ang_ctrl + pi))
Ejemplo n.º 26
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def keyRelay():
	rospy.init_node('keyRelay')
	rate = rospy.Rate(50)
	state_pub = rospy.Publisher('ecu', ECU, queue_size = 10)
	acc = 0
	d_f = 0
	while not rospy.is_shutdown():
		key = getKey()
		print(key)

		acc_d, d_f_d = keyToData(key)
		acc = acc + acc_d
		d_f = d_f + d_f_d

		state_pub.publish( ECU(acc, d_f) )
		rate.sleep()
Ejemplo n.º 27
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def main_auto():
    global read_yaw0, yaw_local

    # initialize ROS node
    init_node('auto_mode', anonymous=True)
    ecu_pub = Publisher('ecu', ECU, queue_size=10)
    se_sub = Subscriber('imu', Imu, imu_callback)

    # set node rate
    rateHz = get_param("controller/rate")
    rate = Rate(rateHz)
    dt = 1.0 / rateHz

    # get PID parameters
    p = get_param("controller/p")
    i = get_param("controller/i")
    d = get_param("controller/d")
    pid = PID(P=p, I=i, D=d)
    setReference = False

    # get experiment parameters
    t_0 = get_param("controller/t_0")  # time to start test
    t_f = get_param("controller/t_f")  # time to end test
    FxR_target = get_param("controller/FxR_target")
    t_params = (t_0, t_f, dt)

    while not is_shutdown():

        # OPEN LOOP
        if read_yaw0:
            # set reference angle
            if not setReference:
                pid.setPoint(yaw_local)
                setReference = True
                t_i = 0.0
                print('yaw_local', yaw_local)
            # apply open loop command
            else:
                (FxR, d_f) = straight(t_i, pid, t_params, FxR_target)
                ecu_cmd = ECU(FxR, -d_f)
                ecu_pub.publish(ecu_cmd)
                t_i += dt

        # wait
        rate.sleep()
Ejemplo n.º 28
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def TwistToECU():

    # initialize node
    rospy.init_node('TwistToECU', anonymous=True)

    global pubname, newECU
    newECU = ECU()
    # topic subscriptions / publications
    pubname = rospy.Publisher('ecu', ECU, queue_size=100)

    rospy.Subscriber('turtle1/cmd_vel', Twist, callback_function)
    # set node rate
    loop_rate = 50
    ts = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)
    t0 = time.time()

    rospy.spin()
Ejemplo n.º 29
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def controller():

    # initialize node
    rospy.init_node('vehicle_simulator', anonymous=True)

    # topic subscriptions / publications
    rospy.Subscriber('z_vhcl', Z_DynBkMdl, measurements_callback)
    rospy.Subscriber('ez_vhcl', eZ_DynBkMdl, measurements_error_frame_callback)

    state_pub = rospy.Publisher('ecu', ECU, queue_size=10)

    # set node rate
    loop_rate = 50
    dt = 1.0 / loop_rate
    rate = rospy.Rate(loop_rate)
    t0 = time.time()

    # set initial conditions
    d_f = 0
    acc = 0

    # reference speed
    v_ref = 8  # reference speed is 8 m/s

    # Initialize the PID controller
    # =====================================tune the gains for PID controller=================================#
    PID_control = PID(kp=1, ki=1, kd=1)
    # =======================================================================================================#

    while not rospy.is_shutdown():
        # acceleration calculated from PID controller.
        acc = PID_control.acc_calculate(v_ref, v_x)

        # steering angle
        d_f = 0.0

        # publish information
        state_pub.publish(ECU(acc, d_f))

        # wait
        rate.sleep()
Ejemplo n.º 30
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def main_auto():

    # initialize ROS node
    init_node('auto_mode', anonymous=True)
    ecu_pub = Publisher('ecu', ECU, queue_size=10)

    # set node rate
    rateHz = get_param("controller/rate")
    rate = Rate(rateHz)
    dt = 1.0 / rateHz

    # get experiment parameters
    FxR_target = get_param("controller/FxR_target")

    while not is_shutdown():

        # OPEN LOOP
        ecu_cmd = ECU(FxR_target, 0)
        ecu_pub.publish(ecu_cmd)
        # wait
        rate.sleep()