Esempio n. 1
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from basicRobot_planner import PathPlanner

grid = PathPlanner()
grid.set_grid([1, 1])
grid.set_grid([0, 1])
grid.set_grid([2, 1])
grid.set_grid([3, 1])
print grid.optimum_policy()
grid.reset_grid([3, 1])
print grid.optimum_policy()
Esempio n. 2
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sensor1 = PORT_1
sensor2 = PORT_2

BrickPi.SensorType[sensor1] = TYPE_SENSOR_ULTRASONIC_CONT
BrickPi.SensorType[sensor2] = TYPE_SENSOR_EV3_GYRO_M0

BrickPi.MotorEnable[motor1] = 1  # Enable the Motor A
BrickPi.MotorEnable[motor2] = 1  # Enable the Motor B
BrickPi.MotorEnable[motor3] = 1  # Enable the Motor C

BrickPiSetupSensors()  # Send the properties of sensors to BrickPi

step = 0
decision = ""
current_position = [0, 0]
grid_object = PathPlanner()
goal = [0, 0]
grid_object.set_goal(goal)
start_coordinates = [0, 0]
end_coordinates = [0, 0]
count = 0
obstruction_flag = False
fs = os.sep
BrickPi.EncoderOffset[motor1] = BrickPi.Encoder[motor1]

while True:
    BrickPiUpdateValues()
    event_handler = MyHandler()
    observer = Observer()
    observer.schedule(event_handler,
                      fs + "home" + fs + "pi" + fs + "Desktop" + fs +
Esempio n. 3
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BrickPi.EncoderOffset[motor1] = BrickPi.Encoder[motor1]
BrickPi.EncoderOffset[motor2] = BrickPi.Encoder[motor2]
BrickPi.EncoderOffset[motor3] = BrickPi.Encoder[motor3]
BrickPiUpdateValues()

ini_coordinates = [
    0, 0
]  # set initial coordinates to be set to user defined coordinates from java_reply.txt
start_coordinates = [0, 0
                     ]  # initialise start coordinates ie. 1st goal coordinates
end_coordinates = [0, 0]  # initialise end coordinates ie. 2nd goal coordinates
step = 0  # steps of execution
current_position = [
    0, 0
]  # initialise current position coordinates to be updated during execution of program
grid_object = PathPlanner()  # define a grid object of PathPlanner class
count = 0  # count the execution number of while loop
obstruction_flag = False  # set on detection of obstruction or after completion of one step of movement
fs = os.sep  # operating system separator
prev_grid = [0, 0]  # initialise previous grid location
prev_movement = ''  # initialise previous movement of vehicle
gyration_angle = 0  # initialise vehicle orientation, U=0, L=-90, R=90, D=180
# movement_step = 700  # set steps for linear motion
rotation_step = 510  # set steps for rotational motion
observer_flag = True  # file system observer flag, detects change in file system


# update the grid-map with the new obstruction coordinate
def obstruction(obst_crd):
    BrickPiUpdateValues()
    grid_object.set_grid(obst_crd)
Esempio n. 4
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sensor3 = PORT_3

BrickPi.SensorType[sensor1] = TYPE_SENSOR_ULTRASONIC_CONT
BrickPi.SensorType[sensor2] = TYPE_SENSOR_ULTRASONIC_CONT
BrickPi.SensorType[sensor3] = TYPE_SENSOR_EV3_GYRO_M0

BrickPi.MotorEnable[motor1] = 1  # Enable the Motor A
BrickPi.MotorEnable[motor2] = 1  # Enable the Motor B
BrickPi.MotorEnable[motor3] = 1  # Enable the Motor C

BrickPiSetupSensors()  # Send the properties of sensors to BrickPi

step = 0
decision = ""
current_position = [0, 0]
grid_object = PathPlanner()
goal = [0, 0]
grid_object.set_goal(goal)

count = 0
BrickPi.EncoderOffset[motor1] = BrickPi.Encoder[motor1]
while True:
    gyro = BrickPi.Sensor[sensor3]

    count += 1
    print "counter", count
    try:
        BrickPiUpdateValues(
        )  # Ask BrickPi to update values for sensors/motors
        obs = obstruction()
        if obstruction() == -1: