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backyard_flyer.py
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backyard_flyer.py
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import sys
sys.path.append(r'C:\Users\kaushik.bhowmik\Documents\GitHub\udacidrone')
import argparse
import time
from enum import Enum
import numpy as np
from udacidrone import Drone
from udacidrone.connection import MavlinkConnection, WebSocketConnection # noqa: F401
from udacidrone.messaging import MsgID
class States(Enum):
MANUAL = 0
ARMING = 1
TAKEOFF = 2
WAYPOINT = 3
LANDING = 4
DISARMING = 5
class BackyardFlyer(Drone):
def __init__(self, connection):
super().__init__(connection)
self.target_position = np.array([0.0, 0.0, 0.0])
self.all_waypoints = []
self.in_mission = True
self.check_state = {}
# initial state
self.flight_state = States.MANUAL
# TODO: Register all your callbacks here
self.register_callback(MsgID.LOCAL_POSITION, self.local_position_callback)
self.register_callback(MsgID.LOCAL_VELOCITY, self.velocity_callback)
self.register_callback(MsgID.STATE, self.state_callback)
def local_position_callback(self):
"""
TODO: Implement this method
This triggers when `MsgID.LOCAL_POSITION` is received and self.local_position contains new data
"""
if self.flight_state==States.TAKEOFF:
if -1* self.local_position[2]>0.95*self.target_position[2]:
self.all_waypoints=self.calculate_box()
self.waypoint_transition()
if self.flight_state==States.WAYPOINT:
if np.linalg.norm(self.target_position[0:2]-self.local_position[0:2])<1.0:
if len(self.all_waypoints)>0:
self.waypoint_transition()
else:
if np.linalg.norm(self.local_velocity[0:2]) < 1.0:
self.landing_transition()
def velocity_callback(self):
"""
TODO: Implement this method
This triggers when `MsgID.LOCAL_VELOCITY` is received and self.local_velocity contains new data
"""
if self.flight_state==States.LANDING:
if self.global_position[2]- self.global_home[2]<0.1 and abs(self.local_position[2])<0.05:
self.disarming_transition()
def state_callback(self):
"""
TODO: Implement this method
This triggers when `MsgID.STATE` is received and self.armed and self.guided contain new data
"""
if self.in_mission:
if self.flight_state==States.MANUAL:
self.arming_transition()
elif self.flight_state==States.ARMING:
if self.armed:
self.takeoff_transition()
elif self.flight_state==States.DISARMING:
if not self.armed:
self.manual_transition()
def calculate_box(self):
"""TODO: Fill out this method
1. Return waypoints to fly a box
"""
print("calculating Box")
l_way_pts=[[10.0,0.0,3.0,0.0],[10.0,10.0,3.0,0.0],[0.0,10.0,3.0,0.0],[0.0,0.0,3.0,0.0]]
return l_way_pts
def arming_transition(self):
"""TODO: Fill out this method
1. Take control of the drone
2. Pass an arming command
3. Set the home location to current position
4. Transition to the ARMING state
"""
print("arming transition")
self.take_control()
self.arm()
self.set_home_position(self.global_position[0],self.global_position[1],self.global_position[2])
self.flight_state = States.ARMING
def takeoff_transition(self):
"""TODO: Fill out this method
1. Set target_position altitude to 3.0m
2. Command a takeoff to 3.0m
3. Transition to the TAKEOFF state
"""
print("takeoff transition")
required_altitude=3
self.target_position[2]=required_altitude
self.takeoff(required_altitude)
self.flight_state= States.TAKEOFF
def waypoint_transition(self):
"""TODO: Fill out this method
1. Command the next waypoint position
2. Transition to WAYPOINT state
"""
print("waypoint transition")
self.target_position= self.all_waypoints.pop(0)
self.cmd_position(self.target_position[0],self.target_position[1],self.target_position[2],0)
self.flight_state=States.WAYPOINT
def landing_transition(self):
"""TODO: Fill out this method
1. Command the drone to land
2. Transition to the LANDING state
"""
print("landing transition")
self.land()
self.flight_state=States.LANDING
def disarming_transition(self):
"""TODO: Fill out this method
1. Command the drone to disarm
2. Transition to the DISARMING state
"""
print("disarm transition")
self.disarm()
self.release_control()
self.flight_state= States.DISARMING
def manual_transition(self):
"""This method is provided
1. Release control of the drone
2. Stop the connection (and telemetry log)
3. End the mission
4. Transition to the MANUAL state
"""
print("manual transition")
self.release_control()
self.stop()
self.in_mission = False
self.flight_state = States.MANUAL
def start(self):
"""This method is provided
1. Open a log file
2. Start the drone connection
3. Close the log file
"""
print("Creating log file")
self.start_log("Logs", "NavLog.txt")
print("starting connection")
self.connection.start()
print("Closing log file")
self.stop_log()
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument('--port', type=int, default=5760, help='Port number')
parser.add_argument('--host', type=str, default='127.0.0.1', help="host address, i.e. '127.0.0.1'")
args = parser.parse_args()
conn = MavlinkConnection('tcp:{0}:{1}'.format(args.host, args.port), threaded=False, PX4=False)
#conn = WebSocketConnection('ws://{0}:{1}'.format(args.host, args.port))
drone = BackyardFlyer(conn)
time.sleep(2)
drone.start()