def buildCube(self):
#Creats a 4x4x4 array to store all the
#LED objects and represent the cube
#all the led pins are initially set to
#1,1 which will be changed later
LedArray = [[[LED(1, 1) for i in range(4)] for j in range(4)]
for k in range(4)]
#A tripple nested for loop where z represents
#what row (Height) we are on, and x and y are
#the coordinate positions of the LED we are
#currently creating.
#
#*Note: the commented number in each if
#represents the GPIO of the row we are on.
for x in range(4):
for y in range(4):
for z in range(4):
if (x == 0):
LedArray[x][y][z] = LED(24, self.colArray[y][z])
#24
elif (x == 1):
LedArray[x][y][z] = LED(23, self.colArray[y][z])
#23
elif (x == 2):
LedArray[x][y][z] = LED(18, self.colArray[y][z])
#18
elif (x == 3):
LedArray[x][y][z] = LED(21, self.colArray[y][z])
#21
#return the created array of LED Objects
return LedArray
def password_entered(self, correct, count_attempt=True):
"""
Resets digit timeout and stores the time of entry. Also handles the attempts count and LEDs.
"""
self.digit_timeout.reset()
self.ignore_digits = True
self.current_input = []
if pi_leds_available:
pi_leds.set_leds(0)
self.access_log_append("code", correct)
if correct:
if PRINT_MSGS:
print("Unlocked!")
self.correct_clear_timeout.restart()
self.incorrect_attempts = 0
self.iface.flash_green_led()
self.logger.log("password correct, attempts reset and LED pulsed")
else:
if count_attempt and USE_MAX_ATTEMPTS:
self.incorrect_attempts += 1
if PRINT_MSGS:
print("Incorrect, you have {} more tries left".format(
MAX_ATTEMPTS - self.incorrect_attempts))
elif count_attempt and not USE_MAX_ATTEMPTS and PRINT_MSGS:
print("Incorrect!")
self.incorrect_clear_timeout.restart()
self.iface.flash_red_led()
if self.incorrect_attempts == MAX_ATTEMPTS:
self.lockout()
self.logger.log(
"password incorrect, attempts: {}, LED pulsed".format(
self.incorrect_attempts))
def turnOnOffLED(GPIOpin, LDR_DO):
if LDR_DO == 1:
print("Dark")
LED.TurnOnLED(GPIOpin)
else:
print("light")
LED.TurnOffLED(GPIOpin)
class IOManager(object):
def __init__(self):
led = 11
button = 13
GPIO.setmode(GPIO.BOARD)
GPIO.setup(led, GPIO.OUT)
self.__scanner = Scanner()
self.__button = Button(button)
self.__led = LED(led)
self.__printer = Printer()
#set up connections and variables for button, light, printer, and scanner
def getButton(self):
return self.__button.getButtonBool()
def getScan(self):
return self.__scanner.getInput()
def setLight(self, value):
self.__led.setValue(value)
def blinkLight(self):
self.__led.blink()
def printReceipt(self, items):
if items:
self.__printer.printHeader()
for item in items:
self.__printer.printItem(item)
self.__printer.printTotals(items)
self.__printer.complete()
def do_blink():
onValue = request.forms.get('on')
offValue = request.forms.get('off')
if onValue and not offValue:
LED.led_on(18)
elif not onValue and offValue:
LED.led_off(18)
return html
def action(selection):
if (selection == 1):
system("echo Shutdown selected!")
LED.ON(10, 0, 0)
system("shutdown now")
elif (selection == 2):
system("echo Restart selected!")
LED.ON(10, 8, 0)
system("reboot now")
async def display_message(ctx):
# Check if there's any stored messages
if len(messageBacklog) > 0:
# Remove message from backlog
msg = messageBacklog.pop(0)
# Send message
await ctx.send("Sending the following message: " + msg)
LED.deconstruct_message(msg)
else:
await ctx.send("There are currently no messages to send!")
def motion(GPIOnum):
global counter
if GPIO.input(GPIOnum):
counter += 1
LED.TurnOnLED(2)
print("Motion detected{0}".format(counter))
else:
LED.TurnOffLED(2)
print("Motion not detected")
def __init__(self, iface, logger, stdout, DEMO_MODE=False):
self.DEMO_MODE = DEMO_MODE
self.iface = iface # store interface wrapper
self.logger = logger # store logger
self.stdout = stdout # store standard output
if not self.DEMO_MODE:
self.stdout.start_overwrite_output()
# bind to digit recevied event
self.iface.digit_received.bind(self.digit_received_handler)
self._digit_timeout_time = None
self.digit_timeout = Timeout(0.1) # the digit timeout
self.digit_timeout.elapsed.bind(self.digit_timeout_elapsed)
self.password = [] # password store
if os.path.isfile(PWORD_FILE): # file exists, read and use
with open(PWORD_FILE) as f:
self.password = f.read().strip() # reads and cleans up
self.logger.log("password read as {}", self.password)
else:
self.password = DEFAULT_PWORD # use default password
self.logger.log("password defaulted to {}", self.password)
with open(PWORD_FILE, "w") as f:
f.write(self.password) # write new password.txt
self.logger.log("wrote new password file to {}", PWORD_FILE)
self.access_log = open(ACCESS_LOG_FILE, "a+")
self.access_log_append("startup", None)
self.current_input = [] # current digit input
self.locked_out = False # whether the user is locked out
# the locked out timeout (supposed to go from 59-0, but should output
# each second)
self.locked_timeout = Timeout(1)
self.locked_timeout.elapsed.bind(self.locked_timeout_elapsed)
self.incorrect_attempts = 0 # the number of incorrect attempts
self.locked_time_left = 0 # the amount of time left for the user to be locked out
self.ignore_digits = False
self.correct_clear_timeout = Timeout(3)
self.correct_clear_timeout.elapsed.bind(self.clear_timeout_elapsed)
self.incorrect_clear_timeout = Timeout(1)
self.incorrect_clear_timeout.elapsed.bind(self.clear_timeout_elapsed)
self.cover_digit_timeout = Timeout(1)
self.cover_digit_timeout.elapsed.bind(self.cover_digit_timeout_elapsed)
if pi_leds_available:
pi_leds.setup_leds()
else:
self.logger.logw(
"unable to import LED lib, RPi LEDs will not be functional")
self.logger.loge(_pi_leds_import_error)
self.logger.log("code lock init complete")
def motion(gpio_num):
global count
if gpio.input(gpio_num):
if gpio.input(23): # if dark
count += 1
LED.turnON(2)
print('Motion detected {}.'.format(count))
print('LDR is {}'.format(gpio.input(23)))
else:
LED.turnOFF(2)
print('Motion not detected')
def boot(duration):
print("*[CUBE - BOOT]*")
IO.setmode(IO.BCM)
IO.setwarnings(0)
ULTRASOUND.setup()
PUMP.setup()
LED.setup()
LED.bootBlinking(duration)
start()
def boot():
print("*[CUBE - BOOT]*")
IO.setmode(IO.BCM)
IO.setwarnings(0)
ULTRASOUND.setup()
PUMP.setup()
LED.setup()
duration = DATA.load_waitForInternetConnection() + BOOTING_EXTRATIME
LED.bootBlinking(duration)
start()
def digit_timeout_elapsed(self):
"""
Handles the elapsed event of the digit timeout.
"""
now = time.time()
passed = now - self._digit_timeout_time
self.logger.logd(
"digit timeout: {} seconds have passed since last input", passed)
if pi_leds_available:
pi_leds.set_leds(max(0, min(passed / DIGIT_TIMEOUT_LENGTH, 1)))
if passed >= DIGIT_TIMEOUT_LENGTH:
self.password_entered(False, False)
self.stdout.overwrite_text = ""
else:
self.digit_timeout.restart()
def setInstance(self, GPIO): if self.useSensor[0] : self.sensorTimerControl.append(DHT11.Control(self.all_pin[0], GPIO, self.topic,[0, 1])) self.sensorTimerControlIndex.append(0) self.sensorTimerControlIndex.append(1) if self.useSensor[1] : self.sensorDetectControl.append(Fire.Control(self.all_pin[1], GPIO, self.topic, 0)) self.sensorDetectControlIndex.append(0) if self.useSensor[2] : self.sensorDetectControl.append(Shock.Control(self.all_pin[4], GPIO, self.topic, 1)) self.sensorDetectControlIndex.append(1) if self.useSensor[3] : self.sensorDetectControl.append(IR.Control(self.all_pin[5], GPIO, self.topic, 2)) self.sensorDetectControlIndex.append(2) if self.useSensor[4] : self.sensorDetectControl.append(Gas.Control(self.adc_pin[0], self.topic, 3)) self.sensorDetectControlIndex.append(3) if self.useSensor[5] : self.sensorTimerControl.append(Cds.Control(self.all_pin[7], GPIO, self.topic, 2)) self.sensorTimerControlIndex.append(2) if self.useSensor[6] : self.button_instance = Button.Control(self.all_pin[6], GPIO, self.topic) if self.useSensor[7] : self.led_instance = LED.LED(self.all_pin[2], self.all_pin[3], GPIO) self.led_instance.write(1) if self.useSensor[8] : self.sensorMoveControl.append(SG90.SG90(self.all_pin[8], self.all_pin[9], GPIO)) if self.useSensor[9] : self.sensorTimerControl.append(PM2008M.Control(self.topic,[3, 4])) self.sensorTimerControlIndex.append(3) self.sensorTimerControlIndex.append(4)
def __init__(self):
#On prépare un fichier temporaire tant que le script est lancé
#pid = str(os.getpid())
#pidfile = "/tmp/controleur.pid"
#try:
# #On teste si le fichier existe déja
# if os.path.isfile(pidfile):
# os.link(pidfile,"daemon_python")
# else:
# file(pidfile, 'w').write(pid)
# os.link(pidfile,"daemon_python")
#except IOError as e:
# message = "I/O error("+str(e.errno)+"): "+str(e.strerror)
# print(message)
#On effectue le vrai travail ici
#On instancie les classes principales
self.stop_event = threading.Event()
self.surveillance_serveur = surveillance_serveur.Surveillance_serveur(
self, self.stop_event)
self.surveillance_serie = surveillance_serie.Surveillance_serie(
self, self.stop_event)
self.traitement = traitement.Traitement(self, self.stop_event)
self.video = video.Video(self.stop_event)
self.led = LED.LED(self.stop_event)
#On met les threads en mode daemon, quand le controleur est tué, on tue tous les threads
self.surveillance_serveur.daemon = True
self.surveillance_serie.daemon = True
self.traitement.daemon = True
self.video.daemon = True
self.led.daemon = True
def led():
while 1:
config = loadConfig()
debugPrint("Mode: " + config["mode"])
if config["mode"] == "static":
LED.fadeToRGB(float(config["static"]["red"]),
float(config["static"]["green"]),
float(config["static"]["blue"]), .25, True)
elif config["mode"] == "breathing":
for color in config["breathing"]:
LED.fadeToRGB(float(color["red"]), float(color["green"]),
float(color["blue"]),
float(color["fadeDuration"]), True)
sleep(float(color["timeout"]))
elif config["mode"] == "disabled":
sleep(1)
def initLEDs(self):
hbox_led = QtGui.QHBoxLayout()
hbox_cb = QtGui.QHBoxLayout()
colors = ['r', 'a', 'y', 'g', 'b', 'p', 'r', 'a']
for i in range(8):
#self.relay_cb.append(Relay_QCheckBox(self, i+1, btn_name, 0, pow(2,i)))
lbl = QtGui.QLabel("Relay " + str(i))
lbl.setAlignment(QtCore.Qt.AlignCenter | QtCore.Qt.AlignVCenter)
lbl.setFixedHeight(20)
lbl.setStyleSheet("QLabel { text-decoration:underline; \
font-size:14px; \
font-weight:bold; \
color:rgb(255,255,255);}")
self.leds.append(LED(i, 50, 'g'))
vbox = QtGui.QVBoxLayout()
vbox.addWidget(lbl)
vbox.addWidget(self.leds[i])
self.leds[i].setAlignment(QtCore.Qt.AlignCenter
| QtCore.Qt.AlignVCenter)
hbox_led.addLayout(vbox)
#hbox_led.setAlignment(QtCore.Qt.AlignCenter|QtCore.Qt.AlignVCenter)
hbox_led.setAlignment(QtCore.Qt.AlignCenter
| QtCore.Qt.AlignVCenter)
#hbox_led.addLayout(vbox_rx)
self.led_fr.setLayout(hbox_led)
def __init__ (self):
'''
A nice debugging aid - can print any simple or complex variable
'''
self.pp = pprint.PrettyPrinter(indent=4)
'''
Create the list of bits
'''
for bitNr in range(8):
b = LED(self.BitNames[bitNr], self.BitPins[bitNr], bitNr, self.BitValues[bitNr], self.BitStates[bitNr], self.BitColors[bitNr], self.BitBlinkRates[bitNr], self.BitProcesses[bitNr], self.BitDescriptions[bitNr])
b.status = self.ledStateString("On", "Off")
self.Bits.append(b)
return None
def __init__(self, car_name):
self.car = Car(car_name)
self.car.steering.turning_max = 50
self.color = self.car.color_getter
self.flag = True
self.buzzer = Buzzer.Buzz()
self.led = LED.Led()
self.song = Buzzer_Elise.Elise()
def watchdog_mode_fnc(frame_image):
gray = cv2.cvtColor(frame_image, cv2.COLOR_BGR2GRAY)
gray = cv2.GaussianBlur(gray, (21, 21), 0)
if avg is None:
print("[INFO] starting background model...")
avg = gray.copy().astype("float")
rawCapture.truncate(0)
return
cv2.accumulateWeighted(gray, avg, 0.5)
frameDelta = cv2.absdiff(gray, cv2.convertScaleAbs(avg))
# threshold the delta image, dilate the thresholded image to fill
# in holes, then find contours on thresholded image
thresh = cv2.threshold(frameDelta, 5, 255, cv2.THRESH_BINARY)[1]
thresh = cv2.dilate(thresh, None, iterations=2)
cnts = cv2.findContours(thresh.copy(), cv2.RETR_EXTERNAL,
cv2.CHAIN_APPROX_SIMPLE)
cnts = imutils.grab_contours(cnts)
#print('x')
# loop over the contours
for c in cnts:
# if the contour is too small, ignore it
if cv2.contourArea(c) < 5000:
return
# compute the bounding box for the contour, draw it on the frame,
# and update the text
(x, y, w, h) = cv2.boundingRect(c)
cv2.rectangle(frame_image, (x, y), (x + w, y + h), (128, 255, 0),
1)
text = "Occupied"
motionCounter += 1
#print(motionCounter)
#print(text)
LED.colorWipe(Color(255, 16, 0))
lastMovtionCaptured = timestamp
if (timestamp - lastMovtionCaptured).seconds >= 0.5:
LED.colorWipe(Color(255, 255, 0))
def __init__(self):
led = 11
button = 13
GPIO.setmode(GPIO.BOARD)
GPIO.setup(led, GPIO.OUT)
self.__scanner = Scanner()
self.__button = Button(button)
self.__led = LED(led)
self.__printer = Printer()
def webhook():
global check
data = request.get_json()
if data["object"] == "page":
for entry in data["entry"]:
for msg_event in entry["messaging"]:
sender_id = msg_event["sender"]["id"]
if msg_event.get("message"):
message_text = msg_event["message"]["text"]
#print(message_text)
if message_text == "turn off led":
LED.Setup(2, "OUT")
LED.TurnOffLED(2)
send_msg("1447614532010378", "turn off led")
#print(message_text)
log(data)
return "ok", 200
def main():
try:
loadConfig()
ledProcess = multiprocessing.Process(target=led)
# ledProcess.start()
# lcdProcess = multiprocessing.Process(target=LCD)
#lcdProcess.start()
monDevice = multiprocessing.Process(target=MonitorDevice)
monDevice.start()
CGISocket.listen(5)
print 'Listening.'
subprocess.Popen(
"sudo sh -c 'echo 1 > /sys/class/leds/led0/brightness'",
shell=True)
while 1:
conn, add = CGISocket.accept()
client(conn, add)
except KeyboardInterrupt:
print "\nGoodbye"
subprocess.Popen(
"sudo sh -c 'echo 0 > /sys/class/leds/led0/brightness'",
shell=True)
# ledProcess.terminate()
LED.fadeToRGB(0, 0, 0, 0.005, False, True)
try:
carConnection.close()
except:
print colored("Failed to close carConnection", "red")
os._exit(0)
except Exception, e:
print "Error!"
print colored(str(e), "red")
traceback.print_exc()
def monitor_distance(LED, min_distance_m=0.1):
'''Monitor distance using ultasonic module and change LED based on distance'''
while True:
current_distance = round(ultra.checkdist(), 2)
if_debug_log("distance: " + str(current_distance))
if current_distance > (2 * min_distance_m):
#distance far, normal white LED
LED.colorWipe(Color(255, 255, 255))
if_debug_log("distance: " + str(current_distance) +
" --> normal, LED white")
elif (current_distance > (min_distance_m) and current_distance <=
(2 * min_distance_m)):
#getting closer, LED yellow
LED.colorWipe(Color(255, 255, 0))
if_debug_log("distance: " + str(current_distance) +
" --> getting closer, LED yellow")
elif current_distance <= min_distance_m:
#too close, LED red
LED.colorWipe(Color(255, 0, 0))
if_debug_log("distance: " + str(current_distance) +
" --> too close, LED red")
def server():
gpio.setmode(gpio.BCM)
LED.setup(21, 'out')
server_socket = bt.BluetoothSocket(bt.RFCOMM)
server_socket.bind(('', 3))
server_socket.listen(1)
conn_socket, address = server_socket.accept()
try:
while True:
data = conn_socket.recv(1024)
data = str(data, 'utf-8')
print(data)
if data == 'turn on':
print('receive "{}"'.format(data))
LED.turnON(21)
elif data == 'turn off':
print('receive "{}"'.format(data))
LED.turnOFF(21)
send_data = input()
conn_socket.send(send_data)
finally:
conn_socket.close()
server_socket.close()
gpio.cleanup()
def server():
bind_ip = '192.168.10.33'
bind_port = 8888
server_socket = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
server_socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
server_socket.bind((bind_ip, bind_port))
server_socket.listen(5)
print('Listening on {}'.format((bind_ip, bind_port)))
gpio.setmode(gpio.BCM)
LED.setup(21, 'out')
try:
conn_socket, addr = server_socket.accept()
print('Accept connection from {}'.format((addr[0], addr[1])))
while True:
data = conn_socket.recv(1024)
data = str(data, 'utf-8')
if data == 'turn on':
LED.turnON(21)
elif data == 'turn off':
LED.turnOFF(21)
print(data)
finally:
server_socket.close()
conn_socket.close()
gpio.cleanup()
def mainLogic():
LED.Blink(5, 5, 5, 1, 2, 3, 1100)
while (True):
GPIO.wait_for_edge(pin, GPIO.FALLING)
sleep(softDebounce) # Software button debounce
count = 0
while (True):
LED.ON(ledMatrix[count][0], ledMatrix[count][1],
ledMatrix[count][2])
isPressed = GPIO.wait_for_edge(pin,
GPIO.FALLING,
timeout=confirmTimeout)
sleep(softDebounce) # Software button debounce
if (isPressed):
count = (count + 1) % 3 # Makes sure the selection is 0-2
if (
count == 0
): # Goes back to start if all options got scrolled through
LED.OFF()
break
else: # Acts when a timeout occurs on non-zero selection
LED.OFF()
action(count)
break
def update():
print("VOLUME - UPDATE")
distanceFull = DATA.load_distanceFull()
distanceEmpty = DATA.load_distanceEmpty()
distance = DATA.load_distance()
range = distanceEmpty - distanceFull
percentage = 0.0
if distance < distanceEmpty:
diffFromEmpty = distanceEmpty - distance
percentage = diffFromEmpty / range
print("VOLUME - UPDATE - PERCENTAGE = [%.2f]" % percentage)
volumeMax = DATA.load_volumeMax()
volume = volumeMax * percentage
print("VOLUME - UPDATE - VOLUME = [%d]" % volume)
DATA.save_volume(volume)
DATA.save_percentage(percentage)
warningPercentage = DATA.load_warningPercentage()
LED.setup()
if percentage < warningPercentage:
LED.red()
shouldSend = DATA.load_shouldSend()
print("********************************************************** SHOULD SEND = ")
print(shouldSend)
if shouldSend:
print("********************************************************** SEND NOTIF")
# sending = DATA.load_sending()
# print("********************************************************** SENDING = ")
# print(sending)
# if not sending:
# DATA.save_sending(1)
# DATA.save_shouldSend(0)
# APNS.sendNotification()
else:
if percentage > 0.5:
print("********************************************************** SHOULD SEND SET TO 1")
DATA.save_shouldSend(1)
LED.blue()
def initTable(self):
self.relay_table = Relay_Table(self.main_window)
self.cb_group = QtGui.QButtonGroup()
self.cb_group.setExclusive(False)
for i in range(8):
#cb = QtGui.QCheckBox("Relay " + str(i))
cb = QtGui.QCheckBox("{:03d}".format(pow(2, i)))
cb.setStyleSheet("QCheckBox { font-size:14px; \
background-color:rgb(0,0,0); \
color:rgb(255,255,255) ; }")
self.cb_group.addButton(cb, i)
rb_on = QtGui.QRadioButton("ON")
rb_on.setStyleSheet("QRadioButton { font-size:14px; \
background-color:rgb(0,0,0); \
color:rgb(255,255,255) ; }")
rb_off = QtGui.QRadioButton("OFF")
rb_off.setStyleSheet("QRadioButton { font-size:14px; \
background-color:rgb(0,0,0); \
color:rgb(255,255,255) ; }")
rb_off.setChecked(True)
self.relay_rb_on.append(rb_on)
self.relay_rb_off.append(rb_off)
self.relay_cb.append(cb)
self.table_led.append(LED(i, 20, 'g'))
self.relay_table.add_relay( self.cfg['relay']['map'][i], \
self.table_led[i], \
self.relay_cb[i], \
self.relay_rb_on[i], \
self.relay_rb_off[i] )
self.relay_cb[i].clicked.connect(self.table_led[i].set_state)
self.cb_group.buttonClicked.connect(self.cbClicked)
grid = QtGui.QGridLayout()
grid.addWidget(self.relay_table, 0, 0, 2, 2)
grid.setSpacing(0)
grid.setContentsMargins(0, 0, 0, 0)
grid.setRowStretch(0, 1)
self.table_fr.setLayout(grid)
def init(s,l):
global screen,led
screen=s
led=LED.create(l)
ico['0']=load('img/0.pbm',25,64)
ico['1']=load('img/1.pbm',25,64)
ico['2']=load('img/2.pbm',25,64)
ico['3']=load('img/3.pbm',25,64)
ico['4']=load('img/4.pbm',25,64)
ico['5']=load('img/5.pbm',25,64)
ico['6']=load('img/6.pbm',25,64)
ico['7']=load('img/7.pbm',25,64)
ico['8']=load('img/8.pbm',25,64)
ico['9']=load('img/9.pbm',25,64)
ico['flash']=load('img/flash.pbm',3,64)
ico['am']=load('img/am.pbm',25,32)
ico['pm']=load('img/pm.pbm',25,32)
ico['cycle']=load('img/cycle.pbm',25,32)
ico['cycle_error']=load('img/cycle_error.pbm',25,32)
ico['love']=load('img/love.pbm',25,32)
def __init__(self):
super(DisplayOLEDSkill, self).__init__(name="DisplayOLEDSkill")
self.myLEDs = LED.theLEDs()
self.myDisplay = DISPLAY.theDisplay()
self.myLEDs.start()
self.myDisplay.start()
GPIO.setmode(GPIO.BCM)
GPIO.setup(self.bshutdown, GPIO.IN, pull_up_down=GPIO.PUD_DOWN)
GPIO.setup(self.brestart, GPIO.IN, pull_up_down=GPIO.PUD_DOWN)
GPIO.setup(self.bsleep1, GPIO.IN, pull_up_down=GPIO.PUD_DOWN)
GPIO.setup(self.bsleep1, GPIO.IN, pull_up_down=GPIO.PUD_DOWN)
GPIO.add_event_detect(self.bshutdown,
GPIO.RISING,
callback=self.button_shutdown)
GPIO.add_event_detect(self.brestart,
GPIO.RISING,
callback=self.button_restart)
GPIO.add_event_detect(self.bsleep1,
GPIO.RISING,
callback=self.button_stop_alarm)
def main():
rfid_reader = SimpleMFRC522.SimpleMFRC522()
temp_sensor = Adafruit_DHT.DHT11
temp_pin = 4 # Physical pin is 7
init() #initialize the GPIO pins
dbh = DB_Helper.DB_Helper()
try:
while True:
print "Please place the tag to the RFID reader."
# Turn ON LED to indicate that RFID is ready for reading
LED.ledON()
# Get the RFID
id, text = rfid_reader.read()
print "RFID: " + str(id)
LED.ledOFF()
# Code for reading the DHT11 Humidity and Temperature Sensor
humidity, temperature = Adafruit_DHT.read_retry(
temp_sensor, temp_pin)
print "Temp={0:0.1f}C Humidity={1:0.1f}%".format(
temperature, humidity)
#Fetch the TagId from db.tbl_Tag base on RFID
tagId = dbh.getTagId(id)
#Insert the temperature, humidity and RFID to Data table
inserted = dbh.addEntry(tagId, temperature, humidity)
# Turn ON the buzzer to indicate that data is sent to Database
if inserted is True:
ActiveBuzzer.beep()
except KeyboardInterrupt:
dbh.destroy()
LED.ledOFF()
cleanGPIO()
import socket
import RPi.GPIO as GPIO
import LED
import sys
bind_ip = '192.168.1.11'
bind_port = 8888
client = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
client.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
server_address = (bind_ip,bind_port)
print('connect to {} port {}'.format(*server_address))
client.connect(server_address)
LED.Setup(14, 'OUT')
try:
print('Accepted connection')
while True:
data = client.recv(1024)
print(data)
if data == b'turn on led':
LED.TurnOnLED(14)
else :
LED.TurnOffLED(14)
except KeyboardInterrupt:
client.close()
GPIO.cleanup()
finally:
server.close()
#!/usr/bin/env python
#encoding=utf-8
from bottle import run, get, post, request
import LED
meta = '<meta name="viewport" content="width=device-width,initial-scale=1.0,user-scalable=yes">'
form = '''
<form action="/bright" method="post">
<input type="range" name="brightvalue" value="0" min="0" max="100">
<input type="submit" value="Bright">
</form>
'''
html = meta + form
led_instance = LED.led_brightness(18)
@get('/bright')
def bright():
return html
@post('/bright')
def do_bright():
sliderValue = request.forms.get('brightvalue')
led_instance.duty(int(sliderValue))
return '%s<br>%s' % (sliderValue, html)
run(host='192.168.18.101', port=8080, debug=True)
while continue_reading:
# Scan for cards
(status,TagType) = MIFAREReader.MFRC522_Request(MIFAREReader.PICC_REQIDL)
# If a card is found
if status == MIFAREReader.MI_OK:
print "Card detected"
# Get the UID of the card
(status,uid) = MIFAREReader.MFRC522_Anticoll()
# If we have the UID, continue
if status == MIFAREReader.MI_OK:
Buzzer.setup()
LED.setup()
Buzzer.beep()
LED.led()
# Print UID
print "Card read UID: "+str(uid[0])+","+str(uid[1])+","+str(uid[2])+","+str(uid[3])
if uid[0]==150 and uid[1]==110 and uid[2]==1 and uid[3]==164:
print "Welcom, Jason :)"
if uid[0]==133 and uid[1]==94 and uid[2]==233 and uid[3]==171:
print "Welcom, Lucy :)"
# This is the default key for authentication
key = [0xFF,0xFF,0xFF,0xFF,0xFF,0xFF]
# Select the scanned tag
GPIO 11 UV_CLOCK
GPIO 10 UV_DOUT
GPIO 21 temperature_CLOCK
GPIO 20 temperature_DOUT
"""
def int16bit(b):
return (ord(b[0]) << 8) + ord(b[1])
arduino = serial.Serial('/dev/ttyACM0', 9600)
pi = pigpio.pi()
led = LED.light(pi)
led.all_off()
pm25 = pmsA003.sensor('/dev/ttyUSB0')
dht = DHT22.sensor(pi, 4)
# Un-comment the line below to convert the temperature to Fahrenheit.
# temperature = temperature * 9/5.0 + 32
# Note that sometimes you won't get a reading and
# the results will be null (because Linux can't
# guarantee the timing of calls to read the sensor).
# If this happens try again!
while True:
def slowBlink(led, numOfBlinks):
for x in range(numOfBlinks):
led.turnOn()
time.sleep(slowBlinkDelay)
led.turnOff()
time.sleep(slowBlinkDelay)
