In GPIO example section we have shown how to detect button presses by using GPIO read() command. Now we will do the same task by using interrupts.
from time import sleep from IoTPy.core.gpio import GPIO from IoTPy.pyuper.uper import UPER1 def button_callback(event, obj): obj['counter'] += 1 print "Interrupt %i" % obj['counter'] button_state = (event['values'] >> event['id']) & 0x1 obj['led'].write(button_state) with UPER1() as board, board.GPIO(27) as redPin, board.GPIO(18) as buttonPin: my_object = {'led': redPin, 'counter': 0} buttonPin.attach_irq(GPIO.CHANGE, button_callback, my_object) redPin.setup(GPIO.OUTPUT) redPin.write(1) while True: sleep(0.5)
This example demonstrates how to use HC-SR501 PIR sensor for motion detection applications, e.g. burglar alarm. The sensor outputs LOW signal when it is idle and HIGH when the motion has been detected.
from time import sleep from IoTPy.core.gpio import GPIO from IoTPy.pyuper.uper import UPER1 def pir_callback(event, obj): print event if event['type'] == GPIO.RISE: print "Movement detected" led.write(0) # turn ON the led elif event['type'] == GPIO.FALL: print "No movement" led.write(1) # turn OFF the led else: print "Unknown event" with UPER1() as board, board.GPIO(27) as led, board.GPIO(18) as button: button.setup(GPIO.INPUT, GPIO.PULL_UP) button.attach_irq(GPIO.CHANGE, pir_callback, led) led.setup(GPIO.OUTPUT) led.write(1) while True: sleep(0.5)
This example shows how to use RotaryEncoder class to detect changes of the rotary switch position.
from IoTPy.pyuper.uper import UPER1 from IoTPy.things.rotary_encoder import RotaryEncoder from time import sleep def on_rotation(direction, position): print "Rotated by %i, current position is %i" % (direction, position) with UPER1() as board, \ board.GPIO(1) as chan0, board.GPIO(2) as chan1, \ RotaryEncoder(chan0, chan1, on_rotation) as encoder: while True: sleep(0.5)
In this example almost all of the work is done by the RotaryEncoder class - it detects changes on the rotary switch pins
and determines the direction of the rotation. For the convenience it also tracks the absolute position. RotaryEncoder class
takes three parameters: the first two are just Interrupt channels to the rotary switch pins and the third one is an optional
user callback function which shall be called on every detected rotation. If you want, you can skip this third parameter and
just track the absolute position via the position
variable. You can also reverse the rotation direction by switching
the signals either physically on breadboard (green and white wires) or in code (Interrupt GPIO IDs 1 and 2).