# Code examples ## Python ### # {#navigate_wait} Fly towards a point and wait for copter's arrival: ```python import math #... def navigate_wait(x=0, y=0, z=0, yaw=float('nan'), speed=0.5, frame_id='', auto_arm=False, tolerance=0.2): navigate(x=x, y=y, z=z, yaw=yaw, speed=speed, frame_id=frame_id, auto_arm=auto_arm) while not rospy.is_shutdown(): telem = get_telemetry(frame_id='navigate_target') if math.sqrt(telem.x ** 2 + telem.y ** 2 + telem.z ** 2) < tolerance: break rospy.sleep(0.2) ``` This function utilizes [`navigate_target`](frames.md#navigate_target) frame for computing the distance to the target. Using the function for flying to the point x=3, y=2, z=1 in [marker's map](aruco_map.md): ```python navigate_wait(x=3, y=2, z=1, frame_id='aruco_map') ``` This function can be used for taking off as well: ```python navigate_wait(z=1, frame_id='body', auto_arm=True) ``` ### # {#block-land} Land and wait until the copter lands: ```python land() while get_telemetry().armed: rospy.sleep(0.2) ``` Usage: ```python land_wait() ``` ### # {#wait_arrival} Wait for copter's arrival to the [navigate](simple_offboard.md#navigate) target: ```python import math # ... def wait_arrival(tolerance=0.2): while not rospy.is_shutdown(): telem = get_telemetry(frame_id='navigate_target') if math.sqrt(telem.x ** 2 + telem.y ** 2 + telem.z ** 2) < tolerance: break rospy.sleep(0.2) ``` ### # {#get_distance} Calculate the distance between two points (**important**: the points are to be in the same [coordinate system](frames.md)): ```python def get_distance(x1, y1, z1, x2, y2, z2): return math.sqrt((x1 - x2) ** 2 + (y1 - y2) ** 2 + (z1 - z2) ** 2) ``` ### # {#get_distance_global} Approximation of distance (in meters) between two global coordinates (latitude/longitude): ```python def get_distance_global(lat1, lon1, lat2, lon2): return math.hypot(lat1 - lat2, lon1 - lon2) * 1.113195e5 ``` ### # {#disarm} Disarm the drone (propellers will stop, **the drone will fall down**): ```python # Declaring a proxy: from mavros_msgs.srv import CommandBool arming = rospy.ServiceProxy('mavros/cmd/arming', CommandBool) # ... arming(False) # disarm ``` ### # {#transform} Transform the position (`PoseStamped`) from one [coordinate system](frames.md) to another using [tf2](http://wiki.ros.org/tf2): ```python import tf2_ros import tf2_geometry_msgs from geometry_msgs.msg import PoseStamped tf_buffer = tf2_ros.Buffer() tf_listener = tf2_ros.TransformListener(tf_buffer) # ... # Create PoseStamped object (or get it from a topic): pose = PoseStamped() pose.header.frame_id = 'map' # coordinate frame, in which the position is specified pose.header.stamp = rospy.get_rostime() # the time for which the position is specified (current time) pose.pose.position.x = 1 pose.pose.position.y = 2 pose.pose.position.z = 3 pose.pose.orientation.w = 1 frame_id = 'base_link' # target coordinate frame transform_timeout = rospy.Duration(0.2) # timeout for transformation # Transform the position from the old frame to the new one: new_pose = tf_buffer.transform(pose, frame_id, transform_timeout) ``` ### # {#upside-down} Determine whether the copter is turned upside-down: ```python PI_2 = math.pi / 2 telem = get_telemetry() flipped = abs(telem.pitch) > PI_2 or abs(telem.roll) > PI_2 ``` ### # {#angle-hor} Calculate the copter horizontal angle: ```python PI_2 = math.pi / 2 telem = get_telemetry() flipped = not -PI_2 <= telem.pitch <= PI_2 or not -PI_2 <= telem.roll <= PI_2 angle_to_horizon = math.atan(math.hypot(math.tan(telem.pitch), math.tan(telem.roll))) if flipped: angle_to_horizon = math.pi - angle_to_horizon ``` ### # {#circle} Fly along a circular path: ```python RADIUS = 0.6 # m SPEED = 0.3 # rad / s start = get_telemetry() start_stamp = rospy.get_rostime() r = rospy.Rate(10) while not rospy.is_shutdown(): angle = (rospy.get_rostime() - start_stamp).to_sec() * SPEED x = start.x + math.sin(angle) * RADIUS y = start.y + math.cos(angle) * RADIUS set_position(x=x, y=y, z=start.z) r.sleep() ``` ### # {#rate} Repeat an action at a frequency of 10 Hz: ```python r = rospy.Rate(10) while not rospy.is_shutdown(): # Do anything r.sleep() ``` ### # {#mavros-sub} An example of subscription to a topic from MAVROS: ```python from geometry_msgs.msg import PoseStamped, TwistStamped from sensor_msgs.msg import BatteryState from mavros_msgs.msg import RCIn # ... def pose_update(pose): # Processing new data of copter's position pass # Other handler functions # ... rospy.Subscriber('/mavros/local_position/pose', PoseStamped, pose_update) rospy.Subscriber('/mavros/local_position/velocity', TwistStamped, velocity_update) rospy.Subscriber('/mavros/battery', BatteryState, battery_update) rospy.Subscriber('mavros/rc/in', RCIn, rc_callback) ``` Information about MAVROS topics is available at [the link](mavros.md). ### # {#mavlink} Send an arbitrary [MAVLink message](mavlink.md) to the copter: ```python # ... from mavros_msgs.msg import Mavlink from mavros import mavlink from pymavlink import mavutil # ... mavlink_pub = rospy.Publisher('mavlink/to', Mavlink, queue_size=1) # Sending a HEARTBEAT message: msg = mavutil.mavlink.MAVLink_heartbeat_message(mavutil.mavlink.MAV_TYPE_GCS, 0, 0, 0, 0, 0) msg.pack(mavutil.mavlink.MAVLink('', 2, 1)) ros_msg = mavlink.convert_to_rosmsg(msg) mavlink_pub.publish(ros_msg) ``` ### # {#rc-sub} React to the drone's mode switching (may be used for starting an autonomous flight, see [example](https://gist.github.com/okalachev/b709f04522d2f9af97e835baedeb806b)): ```python from mavros_msgs.msg import RCIn # Called when new data is received from the transmitter def rc_callback(data): # React on toggling the mode of the transmitter if data.channels[5] < 1100: # ... pass elif data.channels[5] > 1900: # ... pass else: # ... pass # Creating a subscriber for the topic with the data from the transmitter rospy.Subscriber('mavros/rc/in', RCIn, rc_callback) rospy.spin() ``` ### # {#set_mode} Change the [flight mode](modes.md) to arbitrary one: ```python from mavros_msgs.srv import SetMode # ... set_mode = rospy.ServiceProxy('mavros/set_mode', SetMode) # ... set_mode(custom_mode='STABILIZED') ``` ### # {#flip} Flip: ```python import math # ... PI_2 = math.pi / 2 def flip(): start = get_telemetry() # memorize starting position set_rates(thrust=1) # bump up rospy.sleep(0.2) set_rates(pitch_rate=30, thrust=0.2) # pitch flip # set_rates(roll_rate=30, thrust=0.2) # roll flip while True: telem = get_telemetry() flipped = abs(telem.pitch) > PI_2 or abs(telem.roll) > PI_2 if flipped: break rospy.loginfo('finish flip') set_position(x=start.x, y=start.y, z=start.z, yaw=start.yaw) # finish flip print navigate(z=2, speed=1, frame_id='body', auto_arm=True) # take off rospy.sleep(10) rospy.loginfo('flip') flip() ``` Requires the [special PX4 firmware for Clover](firmware.md#modified-firmware-for-clover). Before running a flip, take all necessary safety precautions. ### # {#calibrate-gyro} Perform gyro calibration: ```python from pymavlink import mavutil from mavros_msgs.srv import CommandLong from mavros_msgs.msg import State # ... send_command = rospy.ServiceProxy('/mavros/cmd/command', CommandLong) def calibrate_gyro(): rospy.loginfo('Calibrate gyro') if not send_command(command=mavutil.mavlink.MAV_CMD_PREFLIGHT_CALIBRATION, param1=1).success: return False calibrating = False while not rospy.is_shutdown(): state = rospy.wait_for_message('mavros/state', State) if state.system_status == mavutil.mavlink.MAV_STATE_CALIBRATING or state.system_status == mavutil.mavlink.MAV_STATE_UNINIT: calibrating = True elif calibrating and state.system_status == mavutil.mavlink.MAV_STATE_STANDBY: rospy.loginfo('Calibrating finished') return True calibrate_gyro() ``` > **Note** In process of calibration the drone should not be moved.