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driver.py
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driver.py
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#!/usr/bin/python
"""
Driver for robots with support setSpeedPxPa().
"""
import math
from robot import angleDeg # TODO move to some utils.py (?)
from line import *
from pose import normalizeAnglePIPI
def angleTo( f, t ):
if math.fabs(f[0]-t[0]) < 0.0001 and math.fabs(f[1]-t[1]) < 0.0001:
return 0
return math.atan2( t[1]-f[1], t[0]-f[0] )
class Driver:
def __init__( self, robot, maxSpeed = 1.0, maxAngularSpeed = 2*math.pi ):
# note, that default max limits should be defined by min(Robot,Driver)
self.robot = robot
self.maxSpeed = maxSpeed
self.maxAngularSpeed = maxAngularSpeed
self.centerOffset = 0 # now only for followLineG hacking
def stopDistance( self ):
time = math.fabs(self.robot.currentSpeed/self.robot.maxAcc)+0.15 # system delay
return 0.5 * self.robot.maxAcc * time * time
def stopRotationAngle( self ):
time = math.fabs(self.robot.currentAngularSpeed/self.robot.maxAngularAcc)+0.15 # system delay
return 0.5 * self.robot.maxAngularAcc * time * time
def restrictedTurn( self, turn):
''' Restricts the turn speed to [-maxAngularSpeed, +maxAngularSpeed]. '''
if turn > self.maxAngularSpeed:
return self.maxAngularSpeed
elif turn < -self.maxAngularSpeed:
return -self.maxAngularSpeed
else:
return turn
def restrictedSpeed( self, turn):
'''Restrict the speed with respect to the given rotational velocity.
When turning fast, the forward velocity should be low.
'''
return self.maxSpeed * (0.5 + 0.5 *(1.0 - min(1.0, abs(turn / self.maxAngularSpeed))))
def stopG( self, verbose=False ):
if verbose:
print "---- Driver.stop ----"
for i in range(40): # TODO better avoidance of infinite loop
yield ( 0.0, 0.0 )
if math.fabs(self.robot.currentSpeed) < 0.01 and math.fabs(self.robot.currentAngularSpeed) < angleDeg(5):
break
def stop( self ):
for cmd in self.stopG():
self.robot.setSpeedPxPa( *cmd )
self.robot.update()
def wait(self, duration):
''' Wait for the given amount of time, having the robot stopped. '''
self.robot.setSpeedPxPa(0, 0)
startTime = self.robot.time
while self.robot.time < startTime + duration:
self.robot.update()
def goStraightG( self, dist, speed = None, withStop=True, verbose=False ):
if verbose:
print "---- Driver.goStraight(%.2f) ----" % dist
if speed is None:
speed = self.maxSpeed
if dist >= 0:
while dist > self.stopDistance():
yield ( speed, 0.0 )
dist -= self.robot.lastDistStep
else:
while dist < -self.stopDistance():
yield ( -speed, 0.0 )
dist -= self.robot.lastDistStep
if withStop:
for cmd in self.stopG():
yield cmd
def goStraight( self, dist, speed = None, withStop=True, timeout=None ):
startTime = self.robot.time
for cmd in self.goStraightG( dist, speed, withStop ):
if timeout != None:
if self.robot.time > startTime + timeout:
return False
self.robot.setSpeedPxPa( *cmd )
self.robot.update()
return True
def turnG( self, angle, angularSpeed = None, radius = 0.0, angleThreshold = math.radians(10), withStop=True, verbose=False ):
""" Generator - turn in place (could be even several whole circles)
- caller has to normalize angle if necessary
- radius is positive for forward turn"""
if verbose:
if radius != 0:
print "---- Driver.turn(%d, rad=%.2f) ----" % (int(math.degrees(angle)), radius)
else:
print "---- Driver.turn(%d) ----" % int(math.degrees(angle))
if angularSpeed is None:
angularSpeed = self.maxAngularSpeed
else:
angularSpeed = self.restrictedTurn(angularSpeed)
if math.fabs( angle ) < angleThreshold: # well, there is some minimal limit but ...
return
if angle < 0:
while angle < -self.stopRotationAngle():
yield ( radius*angularSpeed, -angularSpeed )
angle -= self.robot.lastAngleStep
else:
while angle > self.stopRotationAngle():
yield ( radius*angularSpeed, angularSpeed )
angle -= self.robot.lastAngleStep
if withStop:
for cmd in self.stopG():
yield cmd
angle -= self.robot.lastAngleStep
if verbose:
print "---- Driver.turn result(%d) ----" % int(math.degrees(angle))
def turn( self, angle, angularSpeed = None, radius = 0.0, timeout = None, withStop=True, verbose=False ):
startTime = self.robot.time
for cmd in self.turnG( angle, angularSpeed, radius = radius, withStop=withStop, verbose=verbose ):
if timeout != None:
if self.robot.time > startTime + timeout:
return False
self.robot.setSpeedPxPa( *cmd )
self.robot.update()
return True
def followLineG( self, line, stopDistance = 0.0, turnScale = 4.0, offsetSpeed = math.radians(20), offsetDistance = 0.03 ):
'''experimental generator - to replace orig function
line ... A line to follow.
stopDistance ... The robot stops when closer than this to the endpoint. [m]
turnScale ... Magic parameter for the rotational speed. [scaling factor]
offsetSpeed ... This extra rotational speed is added when the robot is too far from the line. [rad/s]
offsetDistance ... When the robot is further than this from the line, some extra correction may be needed. [m]
'''
while line.distanceToFinishLine( self.robot.localisation.pose() ) > stopDistance:
diff = normalizeAnglePIPI( line.angle - self.robot.localisation.pose()[2] );
signedDistance = line.signedDistance( self.robot.localisation.pose() ) + self.centerOffset
# print "deg %.1f" %( math.degrees(diff),), "dist=%0.3f" % (signedDistance,)
if math.fabs( signedDistance ) > offsetDistance:
if signedDistance < 0:
diff += offsetSpeed
else:
diff -= offsetSpeed
turn = self.restrictedTurn(turnScale * diff)
speed = self.restrictedSpeed(turn)
yield speed, turn
def followLine( self, line, stopDistance = 0.0 ):
"deprecated - there will be support of generators only"
for cmd in self.followLineG( line, stopDistance ):
self.robot.setSpeedPxPa( *cmd )
self.robot.update()
def followPolyLineG( self, pts, stopDistance = 0.1, angleThreshold = math.radians(20), turnScale = 4.0, offsetSpeed = math.radians(20), offsetDistance = 0.03 ):
for a,b in zip(pts[:-1],pts[1:]):
print "--- follow (%0.2f,%0.2f) -> (%0.2f,%0.2f) ---" % ( a[0], a[1], b[0], b[1] )
pose = self.robot.localisation.pose()
angleDiff = normalizeAnglePIPI( angleTo(pose, b) - pose[2])
if math.fabs( angleDiff ) > angleThreshold:
for cmd in self.turnG( angleDiff, angleThreshold = angleThreshold ):
yield cmd
line = Line(a,b)
for cmd in self.followLineG( line, stopDistance = stopDistance, turnScale = turnScale, offsetSpeed = offsetSpeed, offsetDistance = offsetDistance ):
yield cmd
for cmd in self.stopG():
yield cmd
def followPolyLine( self, pts ):
for cmd in self.followPolyLineG( pts ):
self.robot.setSpeedPxPa( *cmd )
self.robot.update()
def cmdDaisy( self, pose, goal, maxSpeed ):
angleDiff = normalizeAnglePIPI( angleTo(pose, goal)-pose[2] )
angularSpeed = self.maxAngularSpeed
if angleDiff > math.pi/2.0:
return ( 0.0, angularSpeed )
elif angleDiff < -math.pi/2.0:
return ( 0.0, -angularSpeed )
return math.cos(angleDiff)*maxSpeed, math.sin(angleDiff)*angularSpeed
def followDaisyRouteG( self, route, prediction ):
while True:
pose = self.robot.localisation.pose()
before, future = route.routeSplit( pose )
route.pts = future
if route.length() < prediction:
break
goal = route.pointAtDist( prediction )
if distance( pose, goal ) < 0.01:
goal = route.pointAtDist( 2*prediction )
futureGoal = route.pointAtDist( 3*prediction )
scale = max(distance( pose, futureGoal )/(3*prediction), 0.1) # the robot has to be able to move away
yield self.cmdDaisy( pose, goal, self.maxSpeed*scale )
def goToG( self, target, finishRadius, backward=False, angleThreshold = math.radians(10), angularSpeed = math.radians(10) ):
"generator to reach given destination with given precision"
headingOffset = backward and math.radians(180) or 0.0
prevPose = pose = self.robot.localisation.pose()
angularSpeed = self.restrictedTurn(angularSpeed)
while distance( pose, target ) > finishRadius:
angleDiff = normalizeAnglePIPI( angleTo(pose, target) - pose[2] - headingOffset)
# print angleDiff
if math.fabs( angleDiff ) > angleThreshold:
for cmd in self.turnG( angleDiff, angleThreshold = angleThreshold ):
yield cmd
pose = self.robot.localisation.pose()
if distance( pose, target ) < self.stopDistance():
break
angleDiff = normalizeAnglePIPI( angleTo(pose, target) - pose[2] - headingOffset)
if math.fabs( angleDiff ) > angleThreshold / 2.0:
turn = angularSpeed if angleDiff > 0 else -angularSpeed
else:
turn = math.fabs(angleDiff / angleThreshold / 2.0) * (angularSpeed if angleDiff > 0 else -angularSpeed)
speed = self.restrictedSpeed(turn)
if backward:
speed *= -1
yield ( speed, turn )
for cmd in self.stopG():
yield cmd
def goTo( self, target, finishRadius, backward=False ):
for cmd in self.goToG( target, finishRadius, backward ):
self.robot.setSpeedPxPa( *cmd )
self.robot.update()
def spiralG( self, step, speed = None ):
"generate infinite spiral"
if speed is None:
speed = self.maxSpeed
radius = step
while 1:
gen = self.turnG( math.radians(180.0), angularSpeed=abs(speed/radius), radius=radius, withStop=False )
for cmd in gen:
yield cmd
radius += step/2.0 # semicircles
def multiGen( self, listOfGenerators ):
for gen in listOfGenerators:
for cmd in gen:
yield cmd