本文整理汇总了Python中sensor_msgs.msg.Imu方法的典型用法代码示例。如果您正苦于以下问题:Python msg.Imu方法的具体用法?Python msg.Imu怎么用?Python msg.Imu使用的例子?那么, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类sensor_msgs.msg
的用法示例。
在下文中一共展示了msg.Imu方法的11个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的Python代码示例。
示例1: main
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def main():
if len(sys.argv) < 2:
print("Usage: {} dataset_name".format(sys.argv[0]))
exit(1)
file_name = sys.argv[1]
log_file = h5py.File('../dataset/log/{}.h5'.format(file_name))
camera_file = h5py.File('../dataset/camera/{}.h5'.format(file_name))
zipped_log = izip(
log_file['times'],
log_file['fiber_accel'],
log_file['fiber_gyro'])
with rosbag.Bag('{}.bag'.format(file_name), 'w') as bag:
bar = Bar('Camera', max=len(camera_file['X']))
for i, img_data in enumerate(camera_file['X']):
m_img = Image()
m_img.header.stamp = rospy.Time.from_sec(0.01 * i)
m_img.height = img_data.shape[1]
m_img.width = img_data.shape[2]
m_img.step = 3 * img_data.shape[2]
m_img.encoding = 'rgb8'
m_img.data = np.transpose(img_data, (1, 2, 0)).flatten().tolist()
bag.write('/camera/image_raw', m_img, m_img.header.stamp)
bar.next()
bar.finish()
bar = Bar('IMU', max=len(log_file['times']))
for time, v_accel, v_gyro in zipped_log:
m_imu = Imu()
m_imu.header.stamp = rospy.Time.from_sec(time)
[setattr(m_imu.linear_acceleration, c, v_accel[i]) for i, c in enumerate('xyz')]
[setattr(m_imu.angular_velocity, c, v_gyro[i]) for i, c in enumerate('xyz')]
bag.write('/fiber_imu', m_imu, m_imu.header.stamp)
bar.next()
bar.finish()
示例2: save_imu_data
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def save_imu_data(bag, kitti, imu_frame_id, topic):
print("Exporting IMU")
for timestamp, oxts in zip(kitti.timestamps, kitti.oxts):
q = tf.transformations.quaternion_from_euler(oxts.packet.roll, oxts.packet.pitch, oxts.packet.yaw)
imu = Imu()
imu.header.frame_id = imu_frame_id
imu.header.stamp = rospy.Time.from_sec(float(timestamp.strftime("%s.%f")))
imu.orientation.x = q[0]
imu.orientation.y = q[1]
imu.orientation.z = q[2]
imu.orientation.w = q[3]
imu.linear_acceleration.x = oxts.packet.af
imu.linear_acceleration.y = oxts.packet.al
imu.linear_acceleration.z = oxts.packet.au
imu.angular_velocity.x = oxts.packet.wf
imu.angular_velocity.y = oxts.packet.wl
imu.angular_velocity.z = oxts.packet.wu
bag.write(topic, imu, t=imu.header.stamp)
示例3: __init__
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def __init__(self):
self._MsgData = Imu()
self._MsgPub = rospy.Publisher('/movo/feedback/sic_imu', Imu, queue_size=10)
self._MsgData.header.frame_id = 'sic_imu_frame'
self._seq = 0
示例4: __init__
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def __init__(self):
self.lock = threading.Lock()
self.sub_imu = rospy.Subscriber('imu', Imu, self.imu_cb)
self.last_imu_angle = 0
self.imu_angle = 0
while not rospy.is_shutdown():
self.last_imu_angle = self.imu_angle
rospy.sleep(10)
rospy.loginfo("imu_drift:"+str((self.imu_angle-self.last_imu_angle)*180/3.1415926))
示例5: __init__
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def __init__(self):
self.lock = threading.Lock()
self.sub_imu = rospy.Subscriber('imu', Imu, self.imu_cb)
self.last_imu_angle = 0
self.imu_angle = 0
while not rospy.is_shutdown():
rospy.sleep(0.3)
rospy.loginfo("imu_angle:"+str((self.imu_angle)*180/3.1415926))
示例6: __init__
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def __init__(self):
self.throttleInitialized = False
self.joy_timeout = 2.0
self.lid_timeout = 0.30
self.cnn_timeout = 0.1
self.joy_time = time.time()
self.lid_time = time.time()
self.cnn_time = time.time()
self.controller = XBox360()
self.joy_cmd = TwistStamped()
self.lid_cmd = TwistStamped()
self.cnn_cmd = TwistStamped()
self.cruiseControl = False
self.cruiseThrottle = 0.5
self.steeringAngle = 0.5
self.throttle = 0.5
self.trim = 0.0
##self.throttleLock = Lock()
print "cmd_control"
rospy.Subscriber("/imu", Imu, self.imuCB, queue_size=5)
rospy.Subscriber("/lidar_twist", TwistStamped, self.lidarTwistCB, queue_size=5)
rospy.Subscriber("/neural_twist", TwistStamped, self.neuralTwistCB, queue_size=5)
rospy.Subscriber("/joy", Joy, self.joyCB, queue_size=5)
self.vel_pub = rospy.Publisher("/cmd_vel", TwistStamped, queue_size = 1)
#self.state_pub = rospy.Publisher("/joint_states", JointState, queue_size=1)
self.sound = rospy.Publisher("/sound_server/speech_synth", String, queue_size=1)
rospy.init_node ('cmd_control',anonymous=True)
rate = rospy.Rate(66)
while not rospy.is_shutdown():
self.cmdRouter()
rate.sleep()
示例7: init
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def init():
global q_imu
global fake_measure, fake_distance
q_imu = Imu().orientation
fake_distance = [3.0, 6.0, 0.0, 0.0, 0.0, 0.0]
fake_measure = [3.0, 6.0, 0.0, 0.0, 0.0, 0.0]
rospy.init_node('quaternion_test')
imu_sub = rospy.Subscriber('mavros/imu/data', Imu, imu_callback)
示例8: sensor_data_updated
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def sensor_data_updated(self, carla_imu_measurement):
"""
Function to transform a received imu measurement into a ROS Imu message
:param carla_imu_measurement: carla imu measurement object
:type carla_imu_measurement: carla.IMUMeasurement
"""
imu_msg = Imu()
imu_msg.header = self.get_msg_header(timestamp=carla_imu_measurement.timestamp)
# Carla uses a left-handed coordinate convention (X forward, Y right, Z up).
# Here, these measurements are converted to the right-handed ROS convention
# (X forward, Y left, Z up).
imu_msg.angular_velocity.x = -carla_imu_measurement.gyroscope.x
imu_msg.angular_velocity.y = carla_imu_measurement.gyroscope.y
imu_msg.angular_velocity.z = -carla_imu_measurement.gyroscope.z
imu_msg.linear_acceleration.x = carla_imu_measurement.accelerometer.x
imu_msg.linear_acceleration.y = -carla_imu_measurement.accelerometer.y
imu_msg.linear_acceleration.z = carla_imu_measurement.accelerometer.z
imu_rotation = carla_imu_measurement.transform.rotation
quat = trans.carla_rotation_to_numpy_quaternion(imu_rotation)
imu_msg.orientation = trans.numpy_quaternion_to_ros_quaternion(quat)
self.publish_message(
self.get_topic_prefix(), imu_msg)
示例9: test_imu
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def test_imu(self):
"""
Tests IMU sensor node
"""
rospy.init_node('test_node', anonymous=True)
print("testing for ros bridge")
msg = rospy.wait_for_message("/carla/ego_vehicle/imu", Imu, timeout=15)
self.assertEqual(msg.header.frame_id, "ego_vehicle/imu")
self.assertNotEqual(msg.linear_acceleration, 0.0)
self.assertNotEqual(msg.angular_velocity, 0.0)
self.assertNotEqual(msg.orientation, 0.0)
示例10: handle_received_line
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def handle_received_line(self, line):
"""Calculate orientation from accelerometer and gyrometer"""
self._counter = self._counter + 1
self._SerialPublisher.publish(String(str(self._counter) + ", in: " + line))
if line:
lineParts = line.split('\t')
try:
if lineParts[0] == 'b':
self._battery_value = float(lineParts[1])
self._battery_pub.publish(self._battery_value)
if lineParts[0] == 'i':
# self._qx, self._qy, self._qz, self._qw, \
# self._gx, self._gy, self._gz, \
# self._ax, self._ay, self.az = [float(i) for i in lineParts[1:11]]
self._qx = float(lineParts[1])
self._qy = float(lineParts[2])
self._qz = float(lineParts[3])
self._qw = float(lineParts[4])
self._gx = float(lineParts[5])
self._gy = float(lineParts[6])
self._gz = float(lineParts[7])
self._ax = float(lineParts[8])
self._ay = float(lineParts[9])
self._az = float(lineParts[10])
imu_msg = Imu()
header = Header()
header.stamp = rospy.Time.now()
header.frame_id = self._frame_id
imu_msg.header = header
imu_msg.orientation_covariance = self._imu_data.orientation_covariance
imu_msg.angular_velocity_covariance = self._imu_data.angular_velocity_covariance
imu_msg.linear_acceleration_covariance = self._imu_data.linear_acceleration_covariance
imu_msg.orientation.x = self._qx
imu_msg.orientation.y = self._qy
imu_msg.orientation.z = self._qz
imu_msg.orientation.w = self._qw
imu_msg.angular_velocity.x = self._gx
imu_msg.angular_velocity.y = self._gy
imu_msg.angular_velocity.z = self._gz
imu_msg.linear_acceleration.x = self._ax
imu_msg.linear_acceleration.y = self._ay
imu_msg.linear_acceleration.z = self._az
# q_rot = quaternion_from_euler(self.pi, -self.pi/2, 0)
# q_ori = Quaternion(self._qx, self._qy, self._qz, self._qw)
# imu_msg.orientation = quaternion_multiply(q_ori, q_rot)
self._imu_pub.publish(imu_msg)
except:
rospy.logwarn("Error in Sensor values")
rospy.logwarn(lineParts)
示例11: pub_loop
# 需要导入模块: from sensor_msgs import msg [as 别名]
# 或者: from sensor_msgs.msg import Imu [as 别名]
def pub_loop():
rospy.init_node('state_publisher', anonymous=True)
rospy.Subscriber('/gps/fix', NavSatFix, parse_gps_fix, queue_size=1)
rospy.Subscriber('/gps/vel', TwistWithCovarianceStamped, parse_gps_vel, queue_size=1)
rospy.Subscriber('/imu/data', Imu, parse_imu_data, queue_size=1)
rospy.Subscriber('/vehicle/steering', SteeringReport, parse_steering_angle, queue_size=1)
if not (rospy.has_param('lat0') and rospy.has_param('lon0') and rospy.has_param('yaw0')):
raise ValueError('Invalid rosparam global origin provided!')
if not rospy.has_param('time_check_on'):
raise ValueError('Did not specify if time validity should be checked!')
LAT0 = rospy.get_param('lat0')
LON0 = rospy.get_param('lon0')
YAW0 = rospy.get_param('yaw0')
time_check_on = rospy.get_param('time_check_on')
state_pub = rospy.Publisher('state_est', state_est, queue_size=1)
r = rospy.Rate(100)
while not rospy.is_shutdown():
if None in (lat, lon, psi, vel, acc_filt, df):
r.sleep() # If the vehicle state info has not been received.
continue
curr_state = state_est()
curr_state.header.stamp = rospy.Time.now()
# TODO: time validity check, only publish if data is fresh
#if time_check_on and not time_valid(curr_state.header.stamp,[tm_vel, tm_df, tm_imu, tm_gps]):
# r.sleep()
# continue
curr_state.lat = lat
curr_state.lon = lon
X,Y = latlon_to_XY(LAT0, LON0, lat, lon)
curr_state.x = X
curr_state.y = Y
curr_state.psi = psi
curr_state.v = vel
curr_state.a = acc_filt
curr_state.df = df
state_pub.publish(curr_state)
r.sleep()