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Motion.py
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Motion.py
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__author__ = 'Arthur'
'''
A set of classes to support basic motions for medium motors(for ultra sensor platform), and large motors(for moving).
'''
from ev3.ev3dev import Motor
from Sensor import Gyro
import time
# Driver class used for motion control and attitude adjust
class Driver():
# Wheel motors
left=None
right=None
# Sensors
gyro=None
# Paras
Rrio=2.15 # R_robot/R_wheel: 60/28=2.14285
Wper=175.93 # perimeter of the powering wheels: 175.92919 mm
# Configs
angle=240
rmp_sp=200
run_sp=500 # running speed
t_sp=400 # turning speed
t_accuracy=2 # turning accuracy for Gyro, in degree
r_accuracy=5 # running accuracy for Motor position, in degree
adjust_sp = [100, 50]
def __init__(self):
self.left=Motor(port=Motor.PORT.B)
self.right=Motor(port=Motor.PORT.C)
self.reset()
self.gyro=Gyro()
def reset(self):
self.left.reset()
self.right.reset()
def runForward(self):
self.reset()
self.left.setup_forever(self.run_sp,speed_regulation = True)
self.right.setup_forever(self.run_sp,speed_regulation = True)
self.left.start()
self.right.start()
def forwardbyDistance(self, dist): # distance must be in cm, and positive
if (dist == 0):
return
angle = int(abs(dist*10)/self.Wper*360)
self.forwardbyAngle(angle)
#self.forwardbySecond()
def forwardbyAngle(self, angle):
angtruth = [0, 0]
angtmp = [angle, angle]
# moving and adjusting loop
loop_counter = 0;
while(abs(angtmp[0])>=self.r_accuracy and abs(angtmp[1]) >=self.r_accuracy):
angtruth = self.oneAngleForward(angtmp[0], angtmp[1])
angtmp[0]=angtmp[0]-angtruth[0]
angtmp[1]=angtmp[1]-angtruth[1]
print "fore New angtmp: "+ str(angtmp)
def oneAngleForward(self, left_ang, right_ang):
# run the main movement
self.reset()
self.left.setup_position_limited(position_sp=left_ang, speed_sp=self.run_sp,
stop_mode=Motor.STOP_MODE.HOLD, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.right.setup_position_limited(position_sp=right_ang, speed_sp=self.run_sp,
stop_mode=Motor.STOP_MODE.HOLD, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.left.start()
self.right.start()
time.sleep(10) # need to figure out how much needed
self.stop()
# adjust using low speed mode
for v_adj in self.adjust_sp:
self.left.setup_position_limited(position_sp=left_ang, speed_sp=v_adj,
stop_mode=Motor.STOP_MODE.HOLD, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.right.setup_position_limited(position_sp=right_ang, speed_sp=v_adj,
stop_mode=Motor.STOP_MODE.HOLD, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.left.start()
self.right.start()
time.sleep(1)
return [self.left.position, self.right.position]
def forwardbySecond(self, sec):
self.reset();
self.left.setup_time_limited(time_sp=sec, speed_sp=self.run_sp, speed_regulation=True)
self.right.setup_time_limited(time_sp=sec, speed_sp=self.run_sp, speed_regulation=True)
self.left.start()
self.right.start()
time.sleep(sec)
self.stop()
def runBackward(self):
self.reset()
self.left.setup_forever(-self.run_sp,speed_regulation=True)
self.right.setup_forever(-self.run_sp,speed_regulation=True)
self.left.start()
self.right.start()
def backwardbyDistance(self, dist): # distance must be in cm, and positive
if (dist == 0):
return
angle = -int(abs(dist*10)/self.Wper*360)
self.backwardbyAngle(angle)
def backwardbyAngle(self, angle):
angtruth = [0, 0]
angtmp = [angle, angle]
# moving and adjusting loop
while(abs(angtmp[0])>=self.r_accuracy and abs(angtmp[1]) >=self.r_accuracy):
angtruth = self.oneAngleForward(angtmp[0], angtmp[1])
angtmp[0] = angtmp[0]+angtruth[0]
angtmp[1] = angtmp[1]+angtruth[1]
print "back New angtmp: "+ str(angtmp)
def oneAngleBackward(self, left_ang, right_ang):
self.reset()
self.left.setup_position_limited(position_sp=-left_ang, speed_sp=self.run_sp,
stop_mode=Motor.STOP_MODE.BRAKE, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.right.setup_position_limited(position_sp=-right_ang, speed_sp=self.run_sp,
stop_mode=Motor.STOP_MODE.BRAKE, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.left.start()
self.right.start()
time.sleep(10)
self.stop()
# adjust using low speed mode
for v_adj in self.adjust_sp:
self.left.setup_position_limited(position_sp=-left_ang, speed_sp=v_adj,
stop_mode=Motor.STOP_MODE.HOLD, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.right.setup_position_limited(position_sp=-right_ang, speed_sp=v_adj,
stop_mode=Motor.STOP_MODE.HOLD, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.left.start()
self.right.start()
time.sleep(1)
return [self.left.position, self.right.position]
def turnRightbyAngle(self, ang):
angtruth = 0
angtmp = ang
# moving and adjusting loop
while (abs(angtmp)>self.t_accuracy):
angtruth=self.oneAngleTurnRight(angtmp)
angtmp=angtmp-angtruth
#print "Diff: "+str(angtmp)
def oneAngleTurnRight(self, ang):
before=self.gyro.readAngle()
#print "Before right turn: "+str(before)
self.reset()
self.left.setup_position_limited(position_sp=int(ang*self.Rrio), speed_sp=self.t_sp,
stop_mode=Motor.STOP_MODE.BRAKE, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.right.setup_position_limited(position_sp=-int(ang*self.Rrio), speed_sp=self.t_sp,
stop_mode=Motor.STOP_MODE.BRAKE, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.left.start()
self.right.start()
time.sleep(2)
self.stop()
after=self.gyro.readAngle()
#print "After right turn: "+str(after)
return after - before
def turnLeftbyAngle(self, ang):
angtruth = 0
angtmp = ang
# moving and adjusting loop
while (abs(angtmp)>self.t_accuracy):
angtruth=self.oneAngleTurnLeft(angtmp)
angtmp=angtmp+angtruth
print "Diff: "+str(angtmp)
def oneAngleTurnLeft(self, ang):
before=self.gyro.readAngle()
#print "Before right turn: "+str(before)
self.reset()
self.right.setup_position_limited(position_sp=int(ang*self.Rrio), speed_sp=self.t_sp,
stop_mode=Motor.STOP_MODE.BRAKE, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.left.setup_position_limited(position_sp=-int(ang*self.Rrio), speed_sp=self.t_sp,
stop_mode=Motor.STOP_MODE.BRAKE, ramp_up_sp=self.rmp_sp, ramp_down_sp=self.rmp_sp)
self.right.start()
self.left.start()
time.sleep(2)
self.stop()
after=self.gyro.readAngle()
#print "After right turn: "+str(after)
return after - before
def stop(self):
self.left.stop()
self.right.stop()
# script used for testing
if __name__ == '__main__':
run=1
firstTime=1
k = Driver()
pre_mode = "w"
try:
mode=str(raw_input("command:"))
except ValueError:
print "Wrong key in"
while (True):
print "pre="+pre_mode+" mode="+mode+" firstTime="+str(firstTime)+" run="+str(run)
if (firstTime == 1):
if(mode == "w"):
#k.runForward()
k.forwardbyDistance(10)
firstTime=0
elif(mode == "s"):
#k.runBackward()
k.backwardbyDistance(10)
firstTime=0
elif(mode == "d"):
k.stop()
k.turnRightbyAngle(90)
mode = pre_mode
elif(mode == "a"):
k.stop()
k.turnLeftbyAngle(90)
mode = pre_mode
elif(mode == "z"):
k.stop()
break
firstTime=0
elif(mode == "x"):
k.stop()
firstTime=0
elif(firstTime == 1):
firstTime=0
print "Wrong input"
else:
new_mode = str(raw_input())
if(new_mode != mode):
pre_mode = mode
mode = new_mode
firstTime=1
print "Bye~"