class AutoRobot:
def __init__(self, scanInterval=0.1):
self.sensors = DistanceSensors()
self.robot = Wheels()
self.previousDistance = -1.0
self.previousDirection = Direction.Stop
self.stuckCount = 0
# start distance scanning
if not (self.sensors.StartScanner(scanInterval, True)):
raise SensorException("Distance sensors not working")
def GetDistanceToNextObstacle(self):
'''
Returns the remaining direction, distance in CMs in the current direction of travel
Returns space in forward direction if stopped or rotating
'''
distance = -1.0
if self.robot.direction == Direction.Forward or self.robot.direction == Direction.Stop or \
self.robot.direction == Direction.SpinLeft or self.robot.direction == Direction.SpinRight:
distance = self.sensors.frontDistance[ServoDirection.Ahead]
elif self.robot.direction == Direction.Reverse:
distance = self.sensors.backDistance[ServoDirection.Ahead]
elif self.robot.direction == Direction.ForwardRight:
distance = self.sensors.frontDistance[ServoDirection.OffRight]
elif self.robot.direction == Direction.ForwardLeft:
distance = self.sensors.frontDistance[ServoDirection.OffLeft]
elif self.robot.direction == Direction.ReverseLeft:
distance = self.sensors.backDistance[ServoDirection.OffLeft]
elif self.robot.direction == Direction.ReverseRight:
distance = self.sensors.backDistance[ServoDirection.OffRight]
elif self.robot.direction == Direction.MoveRight:
distance = self.sensors.frontDistance[ServoDirection.Right]
elif self.robot.direction == Direction.MoveLeft:
distance = self.sensors.frontDistance[ServoDirection.Left]
return self.robot.direction, distance
def GetFurthestEnd(self):
'''
Returns direction, distance
Work out if there is more space infront or behind and ignore sides
'''
if self.sensors.backDistance[
ServoDirection.Ahead] > self.sensors.frontDistance[
ServoDirection.Ahead]:
print("Furthest = Reverse",
self.sensors.backDistance[ServoDirection.Ahead])
return Direction.Reverse, self.sensors.backDistance[
ServoDirection.Ahead]
else:
print("Furthest = Forward",
self.sensors.frontDistance[ServoDirection.Ahead])
return Direction.Forward, self.sensors.frontDistance[
ServoDirection.Ahead]
def GetMaxDistanceDirection(self):
'''
Returns servo end, servo direction, distance
Returns the sensor direction with the most space and what that distance is
'''
maxRearDistance = max(self.sensors.backDistance.values())
maxFrontDistance = max(self.sensors.frontDistance.values())
if maxRearDistance > maxFrontDistance:
res = [
key for key in self.sensors.backDistance
if self.sensors.backDistance[key] >= maxRearDistance
]
if abs(self.sensors.backDistance[ServoDirection.Ahead] -
maxRearDistance) < 10:
return ServoEnd.Back, ServoDirection.Ahead, self.sensors.backDistance[
ServoDirection.Ahead]
else:
return ServoEnd.Back, res[0], maxRearDistance
else:
res = [
key for key in self.sensors.frontDistance
if self.sensors.frontDistance[key] >= maxFrontDistance
]
if abs(self.sensors.frontDistance[ServoDirection.Ahead] -
maxFrontDistance) < 10:
return ServoEnd.Front, ServoDirection.Ahead, self.sensors.frontDistance[
ServoDirection.Ahead]
else:
return ServoEnd.Front, res[0], maxFrontDistance
def GetMinDistanceDirection(self):
'''
Returns servo end, servo direction, distance
Returns the sensor direction with the most space and what that distance is
'''
minRearDistance = min(self.sensors.backDistance.values())
minFrontDistance = min(self.sensors.frontDistance.values())
if minRearDistance < minFrontDistance:
res = [
key for key in self.sensors.backDistance
if self.sensors.backDistance[key] <= minRearDistance
]
return ServoEnd.Back, res[0], minRearDistance
else:
res = [
key for key in self.sensors.frontDistance
if self.sensors.frontDistance[key] <= minFrontDistance
]
return ServoEnd.Front, res[0], minFrontDistance
def SetSpeedBasedOnDistance(self, distance):
'''
Set speed based on space infront of us
Return the current speed
'''
if distance < 20.0:
self.robot.Stop()
elif distance < 40.0:
self.robot.Speed(40)
elif distance < 60.0:
self.robot.Speed(50)
elif distance < 100.0:
self.robot.Speed(80)
else:
self.robot.Speed(100)
return self.robot.robotspeed
def RotateToBiggestSpace(self):
'''
Returns direction, distance in new direction of travel
Rotates so either front or rear is pointing to biggests space.
'''
attempts = 5
preferredDirection = self.GetMaxDistanceDirection()
while attempts > 0: # repeat until the front or back is pointing to the biggest space
print("rotating, biggest space is ", preferredDirection)
self.robot.Speed(70)
# work out whether to spin right or left
if (preferredDirection[0] == ServoEnd.Front and
(preferredDirection[1] == ServoDirection.OffRight or preferredDirection[1] == ServoDirection.Right)) or \
(preferredDirection[0] == ServoEnd.Back and
(preferredDirection[1] == ServoDirection.OffLeft or preferredDirection[1] == ServoDirection.Left)):
print("spin right")
self.robot.SpinRight()
else:
print("spin left")
self.robot.SpinLeft()
if ServoDirection.OffLeft or ServoDirection.OffRight:
time.sleep(0.5) # rotate a bit
else:
time.sleep(1.0) # rotate a lot
self.robot.Stop()
# reassess where the biggest space is
preferredDirection = self.GetMaxDistanceDirection()
# if the best direction is forward or reverse don't spin and return
if preferredDirection[1] == ServoDirection.Ahead or \
preferredDirection[1] == ServoDirection.OffLeft or \
preferredDirection[1] == ServoDirection.OffRight:
print("direction chosen", preferredDirection)
if preferredDirection[0] == ServoEnd.Front:
return Direction.Forward, preferredDirection[2]
else:
return Direction.Reverse, preferredDirection[2]
# wait to get new set of distance readings
time.sleep(1)
attempts -= 1
raise StuckException("cannot rotate out of trouble giving up")
def AreWeStuck(self, direction, distance):
'''
Returns True if we haven't moved in the last four checks for being stuck
'''
if abs(
distance - self.previousDistance
) < 1.0 and direction == self.previousDirection and direction != Direction.Stop:
self.stuckCount += 1
if self.stuckCount == 4:
print("Stuck!")
return True
else:
self.stuckCount = 0
return False
def UpdatePosition(self, direction, distance):
'''
Record our current location we we can determine later if we are stuck
'''
self.previousDirection = direction
self.previousDistance = distance
def GetNearestObstacleInDirectionOfTravel(self, currentDirection):
'''
Find out how far away we are from any obstacle directly infront of our direction of travel
'''
nearestObstacle = self.GetMinDistanceDirection()
if nearestObstacle[0] == ServoEnd.Front:
obstacleGeneralDirection = Direction.Forward
else:
obstacleGeneralDirection = Direction.Reverse
if obstacleGeneralDirection != currentDirection:
return 1000.0
return nearestObstacle[2]
robot.Backward()
elif x == 's' or x == '0':
robot.Stop()
elif x == 'l':
robot.SpinLeft()
elif x == 'r':
robot.SpinRight()
elif x == 'mr':
robot.MoveRight()
elif x == 'ml':
robot.MoveLeft()
elif x == 'fr':
robot.MoveForwardRight()
elif x == 'fl':
robot.MoveForwardLeft()
elif x == 'br':
robot.MoveBackwardRight()
elif x == 'bl':
robot.MoveBackwardLeft()
elif x >= '4' and x <= '9':
robot.Speed(int(x) * 10)
elif x > '0' and x <= '3':
robot.Speed(100)
print("Front")
print(sensors.frontDistance)
print("back")
print(sensors.backDistance)
finally:
sensors.StopScanner()
GPIO.cleanup()