PRE2017 3 11 Python Code: Difference between revisions
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__NOTOC__ | __NOTOC__ | ||
==QR scanner with cylinder and platform response== | |||
== | The main script scans QR codes in front of the camera, opens the cylinder and moves the platform down if a correct code is presented. | ||
==Import required packages== | ===Import required packages=== | ||
<pre> | <pre> | ||
#!/usr/bin/python | #!/usr/bin/python | ||
Line 14: | Line 14: | ||
</pre> | </pre> | ||
==Set up constants== | ===Set up constants=== | ||
<pre> | <pre> | ||
Line 35: | Line 35: | ||
imgname = "image2.jpg" # File frame is temporarily saved in | imgname = "image2.jpg" # File frame is temporarily saved in | ||
</pre> | |||
===Imports access codes=== | |||
<pre> | |||
# Imports allowed QRcodes | # Imports allowed QRcodes | ||
passcodelist = [] | passcodelist = [] | ||
Line 124: | Line 126: | ||
</pre> | </pre> | ||
=== | ===Opens/closes the cylinder and moves down the platform=== | ||
<pre> | <pre> | ||
if rightcode: | if rightcode: | ||
servo1.ChangeDutyCycle( | servo1.ChangeDutyCycle(s1right) # Cylinders open | ||
time.sleep(cyldelay) # Duration of cylinder movement | time.sleep(cyldelay) # Duration of cylinder movement | ||
servo1.ChangeDutyCycle(s1center) # Cylinders stop moving | servo1.ChangeDutyCycle(s1center) # Cylinders stop moving | ||
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time.sleep(dropdelay) # Duration of package dropping | time.sleep(dropdelay) # Duration of package dropping | ||
print("Package dropped, cylinders start closing") | print("Package dropped, cylinders start closing") | ||
servo1.ChangeDutyCycle( | servo1.ChangeDutyCycle(s1left) # Cylinders close | ||
time.sleep(cyldelay) # Duration of cylinder movement | time.sleep(cyldelay) # Duration of cylinder movement | ||
servo1.ChangeDutyCycle(s1center) # Cylinders stop moving | servo1.ChangeDutyCycle(s1center) # Cylinders stop moving | ||
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time.sleep(pauzedelay) # Time buffer | time.sleep(pauzedelay) # Time buffer | ||
print("Platform starts moving down") | print("Platform starts moving down") | ||
servo2.ChangeDutyCycle( | servo2.ChangeDutyCycle(s2right) # Platform moves down | ||
time.sleep(platformdelay) # Duration of platform movement | time.sleep(platformdelay) # Duration of platform movement | ||
servo2.ChangeDutyCycle(s2center) # Platform stops moving | servo2.ChangeDutyCycle(s2center) # Platform stops moving | ||
print("Platform stopped moving down, new code can be scanned") | print("Platform stopped moving down, new code can be scanned") | ||
</pre> | |||
==Calibrator== | |||
In order to make sure that the servos rotated exactly long enough, a python script was written which starts and stops the servos on the press of a button: | |||
<pre> | |||
import RPi.GPIO as GPIO # GPIO pin control | |||
import signal # Cleanup when ending script | |||
# Releases pins when script is interrupted | |||
def end_run(signal,frame): | |||
global running | |||
print("Ctrl+C captured, ending script") | |||
running = False | |||
servo1.stop() | |||
servo2.stop() | |||
GPIO.cleanup() | |||
# Runs end_run if ctrl+C is clicked | |||
signal.signal(signal.SIGINT, end_run) | |||
pin_s1 = 29 # Continuous servo 1 | |||
pin_s2 = 33 # Continuous servo 2 | |||
freq = 50 # Continuous servo frequency [Hz] | |||
s1left = 5.00 # 100% velocity to left | |||
s1center = 6.70 # no movement | |||
s1right = 8.00 # 100% velocity to right | |||
s2left = 5.00 # 100% velocity to left | |||
s2center = 6.60 # no movement | |||
s2right = 8.00 # 100% velocity to right | |||
GPIO.setmode(GPIO.BOARD) | |||
GPIO.setup(pin_s1,GPIO.OUT) | |||
GPIO.setup(pin_s2,GPIO.OUT) | |||
servo1 = GPIO.PWM(pin_s1,freq) | |||
servo2 = GPIO.PWM(pin_s2,freq) | |||
servo1.start(s1center) # Starts servos in neutral position | |||
servo2.start(s2center) | |||
running = True | |||
print("1(l,c,r), 2(l,c,r): ") | |||
while running: | |||
n = raw_input() | |||
if n == "1l": | |||
servo1.ChangeDutyCycle(s1left) | |||
elif n == "1c": | |||
servo1.ChangeDutyCycle(s1center) | |||
elif n == "1r": | |||
servo1.ChangeDutyCycle(s1right) | |||
elif n == "2l": | |||
servo2.ChangeDutyCycle(s2left) | |||
elif n == "2c": | |||
servo2.ChangeDutyCycle(s2center) | |||
elif n == "2r": | |||
servo2.ChangeDutyCycle(s2right) | |||
</pre> | |||
==Platform Resetter== | |||
After the storage box is emptied, the platform has to move back up, which is done with the following python code: | |||
<pre> | |||
import RPi.GPIO as GPIO # GPIO pin control | |||
import time | |||
import signal # Cleanup when ending script | |||
# Releases pins when script is interrupted | |||
def end_run(signal,frame): | |||
print("Ctrl+C captured, ending script") | |||
servo2.stop() | |||
GPIO.cleanup() | |||
# Runs end_run if ctrl+C is clicked | |||
signal.signal(signal.SIGINT, end_run) | |||
pin_s2 = 33 # Continuous servo 2 | |||
freq = 50 # Continuous servo frequency [Hz] | |||
s2left = 5.00 # 100% velocity to left | |||
platformdelay = 4.25 # Time it takes for platform to move down | |||
GPIO.setmode(GPIO.BOARD) | |||
GPIO.setup(pin_s2, GPIO.OUT) | |||
servo2 = GPIO.PWM(pin_s2, freq) | |||
servo2.start(s2left) | |||
time.sleep(platformdelay) | |||
servo2.stop() | |||
GPIO.cleanup() | |||
</pre> | |||
==Cylinder Resetter== | |||
If any failures occur when the cylinder is opened, this script can be activated to close the cylinder: | |||
<pre> | |||
import RPi.GPIO as GPIO # GPIO pin control | |||
import time # Posibility to delay | |||
import signal # Cleanup when ending script | |||
pin_s1 = 29 # Continuous servo 1 | |||
freq = 50 # Continuous servo frequency [Hz] | |||
s1left = 5.00 # 100% velocity to left | |||
s1center = 6.70 # no movement | |||
s1right = 8.00 # 100% velocity to right | |||
cyldelay = 1.35 # Time it takes for cylinder to rotate | |||
# Releases pins when script is interrupted | |||
def end_run(signal,frame): | |||
global running | |||
print("Ctrl+C captured, ending script") | |||
running = False | |||
servo1.stop() | |||
servo2.stop() | |||
GPIO.cleanup() | |||
# Runs end_run if ctrl+C is clicked | |||
signal.signal(signal.SIGINT, end_run) | |||
GPIO.setmode(GPIO.BOARD) # Board numbering sceme pins | |||
GPIO.setup(pin_s1, GPIO.OUT) # Sets pins as output | |||
servo1 = GPIO.PWM(pin_s1, freq) # Assigns frequency to pins | |||
servo1.start(s1left) # Starts servos in neutral position | |||
time.sleep(cyldelay) | |||
servo1.stop() | |||
GPIO.cleanup() | |||
</pre> | </pre> |
Latest revision as of 13:37, 2 April 2018
QR scanner with cylinder and platform response
The main script scans QR codes in front of the camera, opens the cylinder and moves the platform down if a correct code is presented.
Import required packages
#!/usr/bin/python from pyzbar.pyzbar import decode # QR reader from PIL import Image # Image reader import cv2 # Image reader import RPi.GPIO as GPIO # GPIO pin control import time # Posibility to delay import signal # Cleanup when ending script import sys # Needed to stop script if no camera
Set up constants
pin_s1 = 29 # Continuous servo 1 pin_s2 = 33 # Continuous servo 2 freq = 50 # Continuous servo frequency [Hz] s1left = 5.00 # 100% velocity to left s1center = 6.70 # no movement s1right = 8.00 # 100% velocity to right s2left = 5.00 # 100% velocity to left s2center = 6.60 # no movement s2right = 8.00 # 100% velocity to right cyldelay = 2 # Time it takes for cylinder to rotate dropdelay = 5 # Time it takes to drop package pauzedelay = 2 # Time between cylinder rotation and platform movement platformdelay = 2 # Time it takes for platform to move down imgname = "image2.jpg" # File frame is temporarily saved in
Imports access codes
# Imports allowed QRcodes passcodelist = [] with open("authcodes") as file: passcodelist = [line.strip() for line in file]
Stops the script safely if CTRL+C is pressed
# Releases pins when script is interrupted def end_run(signal,frame): global running print("Ctrl+C captured, ending script") running = False servo1.stop() servo2.stop() GPIO.cleanup() # Runs end_run if ctrl+C is clicked signal.signal(signal.SIGINT, end_run)
Takes a picture with the camera
# Takes picture from camera, reads and evaluates QRcode def QRscanner(passcodelist, camslot): camera = cv2.VideoCapture(camslot) # Initializes camera viewer grabbed, im = camera.read() # Reads figure
Checks if a picture is taken, and if it is not, it looks for other cameras or stops the script
if not grabbed: # Searches for working camera if camslot < 5: camstr = "No camera connected in slot: " + str(camslot) print(camstr) camslot = camslot + 1 return False, camslot else: print("No camera connected") servo1.stop() servo2.stop() GPIO.cleanup() sys.exit()
Reads QR-codes in the image and checks if a correct code is presented
cv2.imwrite(imgname,im) # Converts image to jpg img = Image.open(imgname) # Reads jpg decodedObjects = decode(img) # Decodes image for obj in decodedObjects: # Makes sure every code is read qrdata = obj.data # Reads the alphanumerical code for passcode in passcodelist: if passcode in qrdata: # Verifies if code is legit print("Correct code, cylinders start opening") return True, camslot else: print("Wrong code") return False, camslot
Sets up the output pins that control the servos
GPIO.setmode(GPIO.BOARD) # Board numbering sceme pins GPIO.setup(pin_s1, GPIO.OUT) # Sets pins as output GPIO.setup(pin_s2, GPIO.OUT) servo1 = GPIO.PWM(pin_s1, freq) # Assigns frequency to pins servo2 = GPIO.PWM(pin_s2, freq) servo1.start(s1center) # Starts servos in neutral position servo2.start(s2center)
Sets up variables, starts the script, and runs the QR-code reader until correct code is presented or CTRL+C is pressed
camslot = 0 # Default camera slot running = True print("Program Running, provide QR-code") while running: rightcode, camslot = QRscanner(passcodelist, camslot) # Runs QR-reader
Opens/closes the cylinder and moves down the platform
if rightcode: servo1.ChangeDutyCycle(s1right) # Cylinders open time.sleep(cyldelay) # Duration of cylinder movement servo1.ChangeDutyCycle(s1center) # Cylinders stop moving print("Cylinders are open, package can be dropped") time.sleep(dropdelay) # Duration of package dropping print("Package dropped, cylinders start closing") servo1.ChangeDutyCycle(s1left) # Cylinders close time.sleep(cyldelay) # Duration of cylinder movement servo1.ChangeDutyCycle(s1center) # Cylinders stop moving print("Cylinders are closed") time.sleep(pauzedelay) # Time buffer print("Platform starts moving down") servo2.ChangeDutyCycle(s2right) # Platform moves down time.sleep(platformdelay) # Duration of platform movement servo2.ChangeDutyCycle(s2center) # Platform stops moving print("Platform stopped moving down, new code can be scanned")
Calibrator
In order to make sure that the servos rotated exactly long enough, a python script was written which starts and stops the servos on the press of a button:
import RPi.GPIO as GPIO # GPIO pin control import signal # Cleanup when ending script # Releases pins when script is interrupted def end_run(signal,frame): global running print("Ctrl+C captured, ending script") running = False servo1.stop() servo2.stop() GPIO.cleanup() # Runs end_run if ctrl+C is clicked signal.signal(signal.SIGINT, end_run) pin_s1 = 29 # Continuous servo 1 pin_s2 = 33 # Continuous servo 2 freq = 50 # Continuous servo frequency [Hz] s1left = 5.00 # 100% velocity to left s1center = 6.70 # no movement s1right = 8.00 # 100% velocity to right s2left = 5.00 # 100% velocity to left s2center = 6.60 # no movement s2right = 8.00 # 100% velocity to right GPIO.setmode(GPIO.BOARD) GPIO.setup(pin_s1,GPIO.OUT) GPIO.setup(pin_s2,GPIO.OUT) servo1 = GPIO.PWM(pin_s1,freq) servo2 = GPIO.PWM(pin_s2,freq) servo1.start(s1center) # Starts servos in neutral position servo2.start(s2center) running = True print("1(l,c,r), 2(l,c,r): ") while running: n = raw_input() if n == "1l": servo1.ChangeDutyCycle(s1left) elif n == "1c": servo1.ChangeDutyCycle(s1center) elif n == "1r": servo1.ChangeDutyCycle(s1right) elif n == "2l": servo2.ChangeDutyCycle(s2left) elif n == "2c": servo2.ChangeDutyCycle(s2center) elif n == "2r": servo2.ChangeDutyCycle(s2right)
Platform Resetter
After the storage box is emptied, the platform has to move back up, which is done with the following python code:
import RPi.GPIO as GPIO # GPIO pin control import time import signal # Cleanup when ending script # Releases pins when script is interrupted def end_run(signal,frame): print("Ctrl+C captured, ending script") servo2.stop() GPIO.cleanup() # Runs end_run if ctrl+C is clicked signal.signal(signal.SIGINT, end_run) pin_s2 = 33 # Continuous servo 2 freq = 50 # Continuous servo frequency [Hz] s2left = 5.00 # 100% velocity to left platformdelay = 4.25 # Time it takes for platform to move down GPIO.setmode(GPIO.BOARD) GPIO.setup(pin_s2, GPIO.OUT) servo2 = GPIO.PWM(pin_s2, freq) servo2.start(s2left) time.sleep(platformdelay) servo2.stop() GPIO.cleanup()
Cylinder Resetter
If any failures occur when the cylinder is opened, this script can be activated to close the cylinder:
import RPi.GPIO as GPIO # GPIO pin control import time # Posibility to delay import signal # Cleanup when ending script pin_s1 = 29 # Continuous servo 1 freq = 50 # Continuous servo frequency [Hz] s1left = 5.00 # 100% velocity to left s1center = 6.70 # no movement s1right = 8.00 # 100% velocity to right cyldelay = 1.35 # Time it takes for cylinder to rotate # Releases pins when script is interrupted def end_run(signal,frame): global running print("Ctrl+C captured, ending script") running = False servo1.stop() servo2.stop() GPIO.cleanup() # Runs end_run if ctrl+C is clicked signal.signal(signal.SIGINT, end_run) GPIO.setmode(GPIO.BOARD) # Board numbering sceme pins GPIO.setup(pin_s1, GPIO.OUT) # Sets pins as output servo1 = GPIO.PWM(pin_s1, freq) # Assigns frequency to pins servo1.start(s1left) # Starts servos in neutral position time.sleep(cyldelay) servo1.stop() GPIO.cleanup()