Esempio n. 1
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def environment(request):
    B=4275
    R0=100000
    lightSensor = mraa.Aio(0)
    a = float(lightSensor.read())
    tempSensor = mraa.Aio(1)
    b = float(tempSensor.read())
    R = 1023/b-1
    R = R0*R
    b = 1/(math.log(R/R0)/B+1/298.15)-273.15
    soundSensor = mraa.Aio(2)
    c = float(soundSensor.read())
    result=""
    if a>300:
        result+="Turn down the light."
    if b>26:
        result+="Turn down the temperature."
    if b<22:
        result+="Turn up the temperature."
    print c
    if c<200:
        result+="Turn down the sound."
    if result=="":
        result="Good environment."
    return HttpResponse(result)
Esempio n. 2
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def initGlobals():
    #File writer
    global writer

    #Hardware related globals
    global main_aio
    global jib_aio
    global collect_aio

    #Sailing related globals
    global heading
    global apWndDir
    global apWndSpd
    global amrRoll
    global cog
    global sog
    global vmg
    global vmgUp
    global truWndDir

    jib_aio = mraa.Aio(2)
    main_aio = mraa.Aio(3)  #TODO confirm these!!!
    collect_aio = mraa.Aio(0)  #Aux 2 for data collection
    amrRoll = 0.0
    heading = 0.0
    apWndDir = 0.0
    apWndSpd = 0.0
    cog = 0.0
    sog = 0.0
    vmg = 0.0
    vmgUp = 0.0
    truWndDir = 0.0
    def __init__(self):
    
        # Important variables.
        self.threads = {}
        self.running = False
        self.last_temperatures = []
        self.last_avg_temp = 0
        self.messages_to_send = []
        self.moment_last_email = datetime.datetime(1970, 1, 1)
        
        # Configure the digital outputs for cold and warm led.
        self.cold_led = mraa.Gpio(COLD_LED)
        self.warm_led = mraa.Gpio(WARM_LED) 
        self.hot_led = mraa.Gpio(HOT_LED)
        self.buzzer = mraa.Gpio(BUZZER_PIN)

        self.cold_led.dir(mraa.DIR_OUT)   
        self.warm_led.dir(mraa.DIR_OUT) 
        self.hot_led.dir(mraa.DIR_OUT) 
        self.buzzer.dir(mraa.DIR_OUT) 
        
        self.cold_led.write(0)
        self.warm_led.write(0)
        self.hot_led.write(0)
        self.buzzer.write(1)

        # Configures the Hi-Z button.
        self.button = mraa.Gpio(BUTTON_PULLUP_PIN) 
        self.button.dir(mraa.DIR_IN)        
        self.button.mode(mraa.MODE_PULLUP)
        self.button.isr(mraa.EDGE_FALLING, button_pressed, self.button)   

        # Configures the ADC.
        self.adc = mraa.Aio(SENSOR_ADC_PIN)
Esempio n. 4
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def publish_message():
    '''
    Description: 
       This function publish light sensor data to the google cloud Pub/Sub.
    Args: 
       None
    Returns:
       None
    Raise:
       Throw an exception on failure
   '''
    try:

        mraa.addSubplatform(mraa.GROVEPI, "0")
        x = mraa.Aio(512)

        while True:
            args.message = "Light Sensor: (%d)" % (x.read())
            cloudApisObj.publish_message_to_subpub(
                args.project_id, args.registry_id, args.device_id,
                args.message_type, args.base_url, args.cloud_region,
                args.algorithm, args.private_key_file, args.message_data_type,
                args.message)
            time.sleep(2)

    except Exception, e:
        print e
Esempio n. 5
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def main():
    #TODO: not sure 100 samples is any more consistent than 16
    n_samples = 100  #The number of analog reads we average to get servo position
    avg_start = 25  #The internal range of data to use in the mean (get rid of outliers)
    avg_end = 75  # " " " upper bound

    analog = mraa.Aio(
        4
    )  #Read from the rudder ADC, fine as long as as all ADC's created equal
    servo.initPWMs()
    servo.hijack()  #Turn the relays to autonomous mode
    for deg in range(0, 90, 5):
        print("Deg: " + str(deg))
        servo.rotate(hackMsg(deg, 0))  #Output the servo
        time.sleep(1)
        for test in range(5):
            print("Test #: " + str(test))
            samps = []
            #Average across middle 50% of multiple reads to reduce noise from ADC
            for samp in range(n_samples):
                samps.append(analog.read())

#Take the middle 50% of samples and average them
            samps.sort()
            val = np.mean(samps[avg_start:avg_end])
            print("Avg ADC value: " + str(val))
            time.sleep(
                0.1)  #TODO this might be an important sleep, not quite sure
        print("")
    def __init__(self):

        # Important variables.
        self.threads = {}
        self.running = False
        self.sensor_value = 0
        self.seconds = 0
        self.mode = 1
        self.pwm_dryer = 0

        # Configure the digital output for the LED 3.
        self.led_system = mraa.Gpio(LED_SYSTEM_PIN)
        self.led_system.dir(mraa.DIR_OUT)

        # Configures the PWM generators (LEDs and dryer).
        self.led_sensor = mraa.Pwm(LED_SENSOR_PWM_PIN)
        self.led_sensor.period_ms(5)

        self.led_dryer = mraa.Pwm(LED_DRYER_PWM_PIN)
        self.led_dryer.period_ms(5)

        # Configures the Hi-Z button, with pull-up and falling edge.
        self.button = mraa.Gpio(BUTTON_PULLUP_PIN)
        self.button.dir(mraa.DIR_IN)
        self.button.mode(mraa.MODE_PULLUP)
        self.button.isr(mraa.EDGE_FALLING, button_pressed, self.button)

        # Configures the ADC.
        self.adc = mraa.Aio(SENSOR_ADC_PIN)

        # Configures the socket.
        self.sock = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)

        # Starts the Network.
        self.network_start()
Esempio n. 7
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 def configureArduinoAdc(self):
     ckboxtree = CheckboxTree(height=6, scroll=0)
     ckboxtree.append(text='ADC 0', item=0, selected=self.checkPinmuxConfig('ADC_0'))
     ckboxtree.append(text='ADC 1', item=1, selected=self.checkPinmuxConfig('ADC_1'))
     ckboxtree.append(text='ADC 2', item=2, selected=self.checkPinmuxConfig('ADC_2'))
     ckboxtree.append(text='ADC 3', item=3, selected=self.checkPinmuxConfig('ADC_3'))
     ckboxtree.append(text='ADC 4', item=4, selected=self.checkPinmuxConfig('ADC_4'))
     ckboxtree.append(text='ADC 5', item=5, selected=self.checkPinmuxConfig('ADC_5'))
     buttonbar = ButtonBar(screen=self.topmenu.gscreen, buttonlist=[('Ok', 'ok'), ('Cancel', 'cancel', 'ESC')])
     g = GridForm(self.topmenu.gscreen,                  # screen
                  'Enable ADC on IO14-IO19',   # title
                  1, 2)                                  # 1x1 grid
     g.add(ckboxtree, 0, 0)
     g.add(buttonbar, 0, 1)
     result = g.runOnce()
     if buttonbar.buttonPressed(result) == 'cancel':
         return
     selected = ckboxtree.getSelection()
     for n in range(0, 6):
         if n in selected:
             aio = mraa.Aio(n)
             self.setPinmuxOfUserConfig('ADC_' + str(n))
         else:
             self.resetPinmuxOfUserConfig('ADC_' + str(n))
     self.saveConfig(self.config)
    def readHumidity(pin):

        sensor = mraa.Aio(pin)
        humidity = sensor.read()
        humidity = (2.4 / 767) * humidity
        humidity = (1 / humidity) * 100
        return humidity
Esempio n. 9
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def getTemp():
	B=3975
	ain = mraa.Aio(3)
	a = ain.read()
	resistance = (1023-a)*10000.0/a
	temp = 1/(math.log(resistance/10000.0)/B+1/298.15)-273.15
	return "{0:.2f}".format(temp)+" graus Celsius"
Esempio n. 10
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    def analog_read(self, pin_number):
        if not pin_number in self.pins["analog"]:
            pin = mraa.Aio(pin_number)
            self.pins["analog"][pin_number] = pin
        else:
            pin = self.pins["analog"][pin_number]

        return pin.read()
Esempio n. 11
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def getSensorData():

    tmp = mraa.Aio(2)
    total = 0.0
    for i in range(0, 5):
        total = total + calculateCelcius(float(tmp.read()))

    celciusVal = total / 5

    sound = mraa.Aio(0)
    soundVal = int(sound.read())

    light = mraa.Aio(3)
    lightVal = int(light.read())

    dic = {'Temperature': celciusVal, 'Sound': soundVal, 'Light': lightVal}
    return json.dumps(dic)
Esempio n. 12
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def first():
    pin = mraa.Aio(0)
    pin.setBit(12)
    rawReading = pin.read()
    volts = float(rawReading / 819.0)
    tempC = (volts * 100) - 50
    tempF = (tempC * 9.0 / 5.0) + 32.0
    return render_template("display_temp.html", name=tempF)
Esempio n. 13
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def tmp():
    try:
        #Initialize the MRAA pin
        pin = mraa.Aio(1)
        #Set it to a 12 bit value
        pin.setBit(12)
    except Exception, e:
        print("Error: {:s}".format(e))
        sys.exit()
Esempio n. 14
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def AIO_init():
    global a_pin
    try:
        a_pin = m.Aio(a_p)
        print("Initializing pin " + str(a_p) + " as AIO")
        return 0
    except ValueError:
        print(sys.exc_info()[1][0])
        return 1
Esempio n. 15
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    def readTemperature(pin):

        B = 3975
        sensor = mraa.Aio(pin)
        aValue = sensor.read()
        resistance = (1023 - aValue) * 10000 / aValue
        celsiusTmp = 1 / (math.log(resistance / 10000) / B +
                          1 / 298.15) - 273.15
        return celsiusTmp
Esempio n. 16
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def AquisicaoDados(fila_tempo, fila_aquisicao):
	
	# Define os pinos 0 (14), ligado ao sensor de temperatura, e o pino 1 (15), ligado ao sensor de luminosidade, como entradas ADC
	adc_temp = mraa.Aio(0)
	adc_lum = mraa.Aio(1)

	while(True):
	  	#Recebe dados da Thread timer (tempo atual, tempo de envio dos dados)
		tempo_atual = fila_tempo.get()  
 
		#Se -1 for enviado pela fila indicando o fim do programa, a thread é desativada
		if(tempo_atual[0] == -1):
			#Envia comando de extinção para proxima thread (ProcessamentoDados)
			fila_aquisicao.put_nowait((-1, 0, 0, tempo_atual[1]))
			break      
		
		# Envia (tempo atual, valor do sensor de temperatura, valor do sendor de luminosidade, tempo de envio de dados) para a thread ProcessamentoDados
		fila_aquisicao.put_nowait((tempo_atual[0], adc_temp.read(), adc_lum.read(), tempo_atual[1]))
Esempio n. 17
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def main():

    #Setup
    duty = 0
    val = 0

    #Servo Constants, duty of 1 outputs abou 3.3 volts
    #Rudder
    period = 3030.0
    duty_min = 1000.0 / period
    duty_max = 2000.0 / period

    #Winches
    # period = 20000.0
    # duty_min = 1100.0/period
    # duty_max=1900.0 /period

    #main is 90 degrees out at duty cycle 0.3 (1 is all the way in)
    #jib is 90 degrees out at duty cycle 0.7 (0 is all the way in)

    #MRAA setup

    #switch to autonomous mode.
    AUTONOMOUS_SELECT_PIN = 2  #2 is for rudder, 4 is main/jib
    auto_select_pin = mraa.Gpio(AUTONOMOUS_SELECT_PIN)
    auto_select_pin.dir(
        mraa.DIR_OUT
    )  #Really important that you set the input/output of the pin...
    auto_select_pin.write(1)

    #PWM_PIN = 6;    #pwm pins are the same as listed on the breakout board. (3 jib, 5 main, 6 rudder)
    #pwm = mraa.Pwm(PWM_PIN);
    #pwm.period_us(int(period));   #Period in microseconds, corresponds to 50Hz like the winch motors.
    #pwm.enable(True);

    #Analog config
    #ANALOG_PIN = 1        #Reading from aux 1
    #ANALOG_PIN=0          #Reading from aux 2
    ANALOG_PIN = 5  #Reading from Rudder
    aio = mraa.Aio(ANALOG_PIN)

    while True:
        val = input("Enter a duty cycle in [0,1]:  ")
        print(val)
        if val < 0 or val > 1:
            print("Duty is out of range")
            continue
        duty = val
        writeval = (duty_min + (duty_max - duty_min) * duty)
        print writeval
        val = aio.read()
        #pwm.write(writeval);       #Scale it according to our ranges

        print('value from analaog ' + str(ANALOG_PIN) + ": " + str(aval))
        print('equivalent to ' + str(aio.read() / 1024.0 * 5.0 * 2.0) +
              ' volts')
Esempio n. 18
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 def __init__(self):
     self.position = (0.0, 0.0)
     self.theta = 0.0
     self.velocity = 0.0
     self.gyro = mraa.Aio(2)
     self.left = mraa.Gpio(2)
     #self.left.isr(mraa.EDGE_RISING, leftbump, leftbump)
     self.right = mraa.Gpio(4)
     #self.right.isr(mraa.EDGE_RISING, rightbump, rightbump)
     self.time = 0
Esempio n. 19
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def get_temp(request):
    temp_pin_number = 1
    temp = mraa.Aio(temp_pin_number)
    temperature = float(temp.read())
    R = 1023.0 / (temperature) - 1.0
    R = 100000.0 * R
    temperature = 1.0 / (math.log(R / 100000.0) / 4275 + 1 / 298.15) - 273.15
    d = {'temperature': temperature}
    print(d)
    return JsonResponse(d)
Esempio n. 20
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 def __init__(self, dht_type, pin):        
     if dht_type != self.DHT_TYPE['DHT11'] and dht_type != self.DHT_TYPE['DHT22']:
         print('ERROR: Please use 11|22 as dht type.')
         exit(1)
     self.dht_type = dht_type
     #self.pin = GPIO(pin, GPIO.OUT)
     self.pin = mraa.Aio(pin)
     #self.pin.dir(mraa.DIR_OUT)
     self._last_temp = 0.0
     self._last_humi = 0.0
Esempio n. 21
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 def set_pin(self, pin):
     """
     initalises the pin for use
     :param pin: GPIO AD pin used for measuring
     :return: initalised mraa class for later  reuse
     """
     if pin not in range (0, 6):
         raise Exception("Incorrect pin selection. Pins available (0, 1, 2, 3, 4, 5)")
     else:
         self.aio = mraa.Aio(pin)
     return self.aio
Esempio n. 22
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 def __init__(self, pin):
     # The sensor length in mm. By default we use 200mm sensor
     # 1 mm
     self.length = 200
     self.low = 0
     self.high = self.length
     self.step = 0.1
     self.sensor = mraa.Aio(pin)
     self.state = self.sensor.readFloat(),
     print("Water level sensor was initialised!")
     return
Esempio n. 23
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def pin_mode(pin,
             pin_type=PIN_TYPE_DIGITAL,
             pin_mode=PIN_MODE_INPUT,
             **kwargs):
    if device_type == DEVICE_TYPE_MRAA:
        if pin_type == PIN_TYPE_DIGITAL:
            if pin_mode == PIN_MODE_INPUT:
                obj = mraa.Gpio(pin)
                obj.dir(mraa.DIR_IN)
                return obj

            elif pin_mode == PIN_MODE_OUTPUT:
                obj = mraa.Gpio(pin)
                obj.dir(mraa.DIR_OUT)
                return obj

        elif pin_type == PIN_TYPE_ANALOG:
            obj = mraa.Aio(pin)
            return obj

        elif pin_type == PIN_TYPE_I2C:
            pass

    elif device_type == DEVICE_TYPE_RPI:
        if pin_type == PIN_TYPE_DIGITAL:
            if pin_mode == PIN_MODE_INPUT:
                GPIO.setup(pin, GPIO.IN, **kwargs)
                return pin

            elif pin_mode == PIN_MODE_OUTPUT:
                GPIO.setup(pin, GPIO.OUT, **kwargs)
                return pin

        else:
            pass

    elif device_type == DEVICE_TYPE_GPI:
        if pin_type == PIN_TYPE_DIGITAL:
            if pin_mode == PIN_MODE_INPUT:
                grovepi.pinMode(pin, "INPUT")
                return pin

            elif pin_mode == PIN_MODE_OUTPUT:
                grovepi.pinMode(pin, "OUTPUT")
                return pin

        elif pin_type == PIN_TYPE_ANALOG:
            grovepi.pinMode(pin, "INPUT")
            return pin

        else:
            pass

    raise NotImplementedError
Esempio n. 24
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def check_voltage():
    ain0 = mraa.Aio(0)
    ain1 = mraa.Aio(1)
    ain2 = mraa.Aio(2)
    ain3 = mraa.Aio(3)
    ain4 = mraa.Aio(4)
    ain5 = mraa.Aio(5)
    ain6 = mraa.Aio(6)

    times = 100
    sum = 0
    values = []

    os.system("echo 59 > /sys/class/gpio/export")
    os.system("echo out > /sys/class/gpio/gpio59/direction")
    os.system("echo 1 > /sys/class/gpio/gpio59/value")
    os.system("echo 117 > /sys/class/gpio/export")
    os.system("echo in > /sys/class/gpio/gpio117/direction")

    # Read GPIO3_21 for 100 times, values HIGH should not less than 30
    while times:
        times = times - 1
        values.append(os.popen("cat  /sys/class/gpio/gpio117/value").read())

    for i in values:
        sum += int(i)
    print "sum: ", sum
    if sum < 30:
        print "GPIO3_21 check fail!"
    else:
        print "GPIO3_21 check ok!"

    VOLTAGES = [
        ["AIN0", 1.50, 1.80, ain0],
        ["AIN2", 0.85, 0.95, ain2],
        ["AIN4", 0.90, 1.30, ain4],
        ["AIN6", 1.42, 1.58, ain6],
        ["AIN1", 1.04, 1.16, ain1],  # VDD_3V3B / 3
        ["AIN3", 1.40, 1.75, ain3],  # VDD_5V   / 3
        ["AIN5", 1.40, 1.80, ain5]
    ]  # SYS_5V   / 3

    # ADC.setup()
    result = []
    status = 'ok'
    for v in VOLTAGES:
        ain = v[3].read() / 1024.0 * 1.8  #ain = ADC.read(v[0])*1.8
        #print ain
        if ain < v[1] or ain > v[2]:
            result.append('%f (%s) is out of range: %f ~ %f.' %
                          (ain, v[0], v[1], v[2]))
            status = 'error'
        else:
            result.append('%f (%s) is in of range: %f ~ %f.' %
                          (ain, v[0], v[1], v[2]))
    return status, result
Esempio n. 25
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def parse_data():  #sensor number
    i = 0
    data1 = []
    data2 = []
    data3 = []
    data4 = []
    avg_data1 = 0
    avg_data2 = 0
    avg_data3 = 0
    avg_data4 = 0
    avg_data = []
    while (i < 10):
        d1 = mraa.Aio(0)  #reading value from sensor
        d2 = mraa.Aio(1)
        d3 = mraa.Aio(2)
        d4 = mraa.Aio(3)
        data1.append(d1.read())  #reading value from data variable
        data2.append(d2.read())
        data3.append(d3.read())
        data4.append(d4.read())
        i += 1
        time.sleep(.001)

    for x in data1:  #adding data together
        x = int(x)
        avg_data1 = avg_data1 + x
    for x in data2:
        x = int(x)
        avg_data2 = avg_data2 + x
    for x in data3:
        x = int(x)
        avg_data3 = avg_data3 + x
    for x in data4:
        x = int(x)
        avg_data4 = avg_data4 + x
    avg_data.append(avg_data1 / len(data1))  #averaging data
    avg_data.append(avg_data2 / len(data2))
    avg_data.append(avg_data3 / len(data3))
    avg_data.append(avg_data4 / len(data4))

    return avg_data
Esempio n. 26
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def get_uv():
    try:
        uv_sensor = mraa.Aio(3)
        Vsig = uv_sensor.readFloat()
        intensity = 307 * Vsig # 307 taken from documentation.
        msg = ''
        uv_idx = intensity // 200
#        print uv_idx
        return uv_idx
    except IOError:
        print 'IO Error!'
        return
Esempio n. 27
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def readingSensorValue(queueSensor, cont, pin):
    # Hook the SIGINT
    signal.signal(signal.SIGINT, signal.SIG_IGN)
    light = mraa.Aio(pin)
    while cont.value:
        # Read interger value
        sensorIntegerLight = light.read()
        queueSensor.put({
            "type": "LIGHT_SENSOR",
            "payload": sensorIntegerLight
        })
        time.sleep(1)
Esempio n. 28
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def temp():
    B = 4275
    R0 = 100000
    try:
        tempSensor = mraa.Aio(1)
        a = tempSensor.read()
        R = 1023.0 / a - 1.0
        R = R0 * R
        v = 1.0 / (log(R / R0) / B + 1 / 298.15) - 273.15
        print(v), "is the current temperature"
        return v
    except KeyboardInterrupt:
        return None
Esempio n. 29
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def setup():
	global Light
	Light = mraa.Gpio(8)  
	Light.dir(mraa.DIR_OUT) 

	global sensorPin
	sensorPin = mraa.Aio(5)

	global BaseStepper
	BaseStepper = Stepper(10,11,9,'eighth_step')

	global ReceiverStepper
	ReceiverStepper = Stepper(7,6,2,'eighth_step')
	ReceiverStepper.rotateMotor(45)
def dataVolt(): # Get Voltage and current data
   xpt=0.0
   try:
      xpi= mraa.Aio(0)
      for i in range (25):
         xp = xpi.readFloat()  #(xp + xpi.readFloat())
         xpt=xp+xpt
         print xp
         print xpt
      xv=xpt / 25
      print ('The current value is= ', xv)
   except:
      print ("Error capturing the Voltage(V) value data...")
   return xv