uPyLibs/bme280.py

import time
from ustruct import unpack, unpack_from
from array import array

# BME280 default address.
BME280_I2CADDR = 0x76

# Operating Modes
BME280_OSAMPLE_1 = 1
BME280_OSAMPLE_2 = 2
BME280_OSAMPLE_4 = 3
BME280_OSAMPLE_8 = 4
BME280_OSAMPLE_16 = 5

BME280_REGISTER_CONTROL_HUM = 0xF2
BME280_REGISTER_CONTROL = 0xF4


class BME280:
    def __init__(self,
                 mode=BME280_OSAMPLE_1,
                 address=BME280_I2CADDR,
                 i2c=None,
                 **kwargs):
        # Check that mode is valid.
        if mode not in [BME280_OSAMPLE_1, BME280_OSAMPLE_2, BME280_OSAMPLE_4,
                        BME280_OSAMPLE_8, BME280_OSAMPLE_16]:
            raise ValueError(
                'Unexpected mode value {0}. Set mode to one of '
                'BME280_ULTRALOWPOWER, BME280_STANDARD, BME280_HIGHRES, or '
                'BME280_ULTRAHIGHRES'.format(mode))
        self._mode = mode
        self.address = address
        if i2c is None:
            raise ValueError('An I2C object is required.')
        self.i2c = i2c

        # load calibration data
        dig_88_a1 = self.i2c.readfrom_mem(self.address, 0x88, 26)
        dig_e1_e7 = self.i2c.readfrom_mem(self.address, 0xE1, 7)
        self.dig_T1, self.dig_T2, self.dig_T3, self.dig_P1, \
        self.dig_P2, self.dig_P3, self.dig_P4, self.dig_P5, \
        self.dig_P6, self.dig_P7, self.dig_P8, self.dig_P9, \
        _, self.dig_H1 = unpack("<HhhHhhhhhhhhBB", dig_88_a1)

        self.dig_H2, self.dig_H3 = unpack("<hB", dig_e1_e7)
        e4_sign = unpack_from("<b", dig_e1_e7, 3)[0]
        self.dig_H4 = (e4_sign << 4) | (dig_e1_e7[4] & 0xF)

        e6_sign = unpack_from("<b", dig_e1_e7, 5)[0]
        self.dig_H5 = (e6_sign << 4) | (dig_e1_e7[4] >> 4)

        self.dig_H6 = unpack_from("<b", dig_e1_e7, 6)[0]

        self.i2c.writeto_mem(self.address, BME280_REGISTER_CONTROL,
                             bytearray([0x3F]))
        self.t_fine = 0

        # temporary data holders which stay allocated
        self._l1_barray = bytearray(1)
        self._l8_barray = bytearray(8)
        self._l3_resultarray = array("i", [0, 0, 0])

    def read_raw_data(self, result):
        """ Reads the raw (uncompensated) data from the sensor.

            Args:
                result: array of length 3 or alike where the result will be
                stored, in temperature, pressure, humidity order
            Returns:
                None
        """

        self._l1_barray[0] = self._mode
        self.i2c.writeto_mem(self.address, BME280_REGISTER_CONTROL_HUM,
                             self._l1_barray)
        self._l1_barray[0] = self._mode << 5 | self._mode << 2 | 1
        self.i2c.writeto_mem(self.address, BME280_REGISTER_CONTROL,
                             self._l1_barray)

        sleep_time = 1250 + 2300 * (1 << self._mode)
        sleep_time = sleep_time + 2300 * (1 << self._mode) + 575
        sleep_time = sleep_time + 2300 * (1 << self._mode) + 575
        time.sleep_us(sleep_time)  # Wait the required time

        # burst readout from 0xF7 to 0xFE, recommended by datasheet
        self.i2c.readfrom_mem_into(self.address, 0xF7, self._l8_barray)
        readout = self._l8_barray
        # pressure(0xF7): ((msb << 16) | (lsb << 8) | xlsb) >> 4
        raw_press = ((readout[0] << 16) | (readout[1] << 8) | readout[2]) >> 4
        # temperature(0xFA): ((msb << 16) | (lsb << 8) | xlsb) >> 4
        raw_temp = ((readout[3] << 16) | (readout[4] << 8) | readout[5]) >> 4
        # humidity(0xFD): (msb << 8) | lsb
        raw_hum = (readout[6] << 8) | readout[7]

        result[0] = raw_temp
        result[1] = raw_press
        result[2] = raw_hum

    def read_compensated_data(self, result=None):
        """ Reads the data from the sensor and returns the compensated data.

            Args:
                result: array of length 3 or alike where the result will be
                stored, in temperature, pressure, humidity order. You may use
                this to read out the sensor without allocating heap memory

            Returns:
                array with temperature, pressure, humidity. Will be the one from
                the result parameter if not None
        """
        self.read_raw_data(self._l3_resultarray)
        raw_temp, raw_press, raw_hum = self._l3_resultarray
        # temperature
        var1 = ((raw_temp >> 3) - (self.dig_T1 << 1)) * (self.dig_T2 >> 11)
        var2 = (((((raw_temp >> 4) - self.dig_T1) *
                  ((raw_temp >> 4) - self.dig_T1)) >> 12) * self.dig_T3) >> 14
        self.t_fine = var1 + var2
        temp = (self.t_fine * 5 + 128) >> 8

        # pressure
        var1 = self.t_fine - 128000
        var2 = var1 * var1 * self.dig_P6
        var2 = var2 + ((var1 * self.dig_P5) << 17)
        var2 = var2 + (self.dig_P4 << 35)
        var1 = (((var1 * var1 * self.dig_P3) >> 8) +
                ((var1 * self.dig_P2) << 12))
        var1 = (((1 << 47) + var1) * self.dig_P1) >> 33
        if var1 == 0:
            pressure = 0
        else:
            p = 1048576 - raw_press
            p = (((p << 31) - var2) * 3125) // var1
            var1 = (self.dig_P9 * (p >> 13) * (p >> 13)) >> 25
            var2 = (self.dig_P8 * p) >> 19
            pressure = ((p + var1 + var2) >> 8) + (self.dig_P7 << 4)

        # humidity
        h = self.t_fine - 76800
        h = (((((raw_hum << 14) - (self.dig_H4 << 20) -
                (self.dig_H5 * h)) + 16384)
              >> 15) * (((((((h * self.dig_H6) >> 10) *
                            (((h * self.dig_H3) >> 11) + 32768)) >> 10) +
                          2097152) * self.dig_H2 + 8192) >> 14))
        h = h - (((((h >> 15) * (h >> 15)) >> 7) * self.dig_H1) >> 4)
        h = 0 if h < 0 else h
        h = 419430400 if h > 419430400 else h
        humidity = h >> 12

        if result:
            result[0] = temp
            result[1] = pressure
            result[2] = humidity
            return result

        return array("i", (temp, pressure, humidity))

    @property
    def values(self):
        """ human readable values """

        t, p, h = self.read_compensated_data()

        p = p // 256
        pi = p // 100
        pd = p - pi * 100

        hi = h // 1024
        hd = h * 100 // 1024 - hi * 100
        return ("{}C".format(t / 100), "{}.{:02d}hPa".format(pi, pd),
                "{}.{:02d}%".format(hi, hd))
add BME280 support (untested) 2018-05-31 20:46:29 +01:00			`import time`
			`from ustruct import unpack, unpack_from`
			`from array import array`

			`# BME280 default address.`
			`BME280_I2CADDR = 0x76`

			`# Operating Modes`
			`BME280_OSAMPLE_1 = 1`
			`BME280_OSAMPLE_2 = 2`
			`BME280_OSAMPLE_4 = 3`
			`BME280_OSAMPLE_8 = 4`
			`BME280_OSAMPLE_16 = 5`

			`BME280_REGISTER_CONTROL_HUM = 0xF2`
			`BME280_REGISTER_CONTROL = 0xF4`


			`class BME280:`
			`def __init__(self,`
			`mode=BME280_OSAMPLE_1,`
			`address=BME280_I2CADDR,`
			`i2c=None,`
			`**kwargs):`
			`# Check that mode is valid.`
			`if mode not in [BME280_OSAMPLE_1, BME280_OSAMPLE_2, BME280_OSAMPLE_4,`
			`BME280_OSAMPLE_8, BME280_OSAMPLE_16]:`
			`raise ValueError(`
			`'Unexpected mode value {0}. Set mode to one of '`
			`'BME280_ULTRALOWPOWER, BME280_STANDARD, BME280_HIGHRES, or '`
			`'BME280_ULTRAHIGHRES'.format(mode))`
			`self._mode = mode`
			`self.address = address`
			`if i2c is None:`
			`raise ValueError('An I2C object is required.')`
			`self.i2c = i2c`

			`# load calibration data`
			`dig_88_a1 = self.i2c.readfrom_mem(self.address, 0x88, 26)`
			`dig_e1_e7 = self.i2c.readfrom_mem(self.address, 0xE1, 7)`
			`self.dig_T1, self.dig_T2, self.dig_T3, self.dig_P1, \`
			`self.dig_P2, self.dig_P3, self.dig_P4, self.dig_P5, \`
			`self.dig_P6, self.dig_P7, self.dig_P8, self.dig_P9, \`
			`_, self.dig_H1 = unpack("<HhhHhhhhhhhhBB", dig_88_a1)`

			`self.dig_H2, self.dig_H3 = unpack("<hB", dig_e1_e7)`
			`e4_sign = unpack_from("<b", dig_e1_e7, 3)[0]`
			`self.dig_H4 = (e4_sign << 4) \| (dig_e1_e7[4] & 0xF)`

			`e6_sign = unpack_from("<b", dig_e1_e7, 5)[0]`
			`self.dig_H5 = (e6_sign << 4) \| (dig_e1_e7[4] >> 4)`

			`self.dig_H6 = unpack_from("<b", dig_e1_e7, 6)[0]`

			`self.i2c.writeto_mem(self.address, BME280_REGISTER_CONTROL,`
			`bytearray([0x3F]))`
			`self.t_fine = 0`

			`# temporary data holders which stay allocated`
			`self._l1_barray = bytearray(1)`
			`self._l8_barray = bytearray(8)`
			`self._l3_resultarray = array("i", [0, 0, 0])`

			`def read_raw_data(self, result):`
			`""" Reads the raw (uncompensated) data from the sensor.`

			`Args:`
			`result: array of length 3 or alike where the result will be`
			`stored, in temperature, pressure, humidity order`
			`Returns:`
			`None`
			`"""`

			`self._l1_barray[0] = self._mode`
			`self.i2c.writeto_mem(self.address, BME280_REGISTER_CONTROL_HUM,`
			`self._l1_barray)`
			`self._l1_barray[0] = self._mode << 5 \| self._mode << 2 \| 1`
			`self.i2c.writeto_mem(self.address, BME280_REGISTER_CONTROL,`
			`self._l1_barray)`

			`sleep_time = 1250 + 2300 * (1 << self._mode)`
			`sleep_time = sleep_time + 2300 * (1 << self._mode) + 575`
			`sleep_time = sleep_time + 2300 * (1 << self._mode) + 575`
			`time.sleep_us(sleep_time) # Wait the required time`

			`# burst readout from 0xF7 to 0xFE, recommended by datasheet`
			`self.i2c.readfrom_mem_into(self.address, 0xF7, self._l8_barray)`
			`readout = self._l8_barray`
			`# pressure(0xF7): ((msb << 16) \| (lsb << 8) \| xlsb) >> 4`
			`raw_press = ((readout[0] << 16) \| (readout[1] << 8) \| readout[2]) >> 4`
			`# temperature(0xFA): ((msb << 16) \| (lsb << 8) \| xlsb) >> 4`
			`raw_temp = ((readout[3] << 16) \| (readout[4] << 8) \| readout[5]) >> 4`
			`# humidity(0xFD): (msb << 8) \| lsb`
			`raw_hum = (readout[6] << 8) \| readout[7]`

			`result[0] = raw_temp`
			`result[1] = raw_press`
			`result[2] = raw_hum`

			`def read_compensated_data(self, result=None):`
			`""" Reads the data from the sensor and returns the compensated data.`

			`Args:`
			`result: array of length 3 or alike where the result will be`
			`stored, in temperature, pressure, humidity order. You may use`
			`this to read out the sensor without allocating heap memory`

			`Returns:`
			`array with temperature, pressure, humidity. Will be the one from`
			`the result parameter if not None`
			`"""`
			`self.read_raw_data(self._l3_resultarray)`
			`raw_temp, raw_press, raw_hum = self._l3_resultarray`
			`# temperature`
			`var1 = ((raw_temp >> 3) - (self.dig_T1 << 1)) * (self.dig_T2 >> 11)`
			`var2 = (((((raw_temp >> 4) - self.dig_T1) *`
			`((raw_temp >> 4) - self.dig_T1)) >> 12) * self.dig_T3) >> 14`
			`self.t_fine = var1 + var2`
			`temp = (self.t_fine * 5 + 128) >> 8`

			`# pressure`
			`var1 = self.t_fine - 128000`
			`var2 = var1 * var1 * self.dig_P6`
			`var2 = var2 + ((var1 * self.dig_P5) << 17)`
			`var2 = var2 + (self.dig_P4 << 35)`
			`var1 = (((var1 * var1 * self.dig_P3) >> 8) +`
			`((var1 * self.dig_P2) << 12))`
			`var1 = (((1 << 47) + var1) * self.dig_P1) >> 33`
			`if var1 == 0:`
			`pressure = 0`
			`else:`
			`p = 1048576 - raw_press`
			`p = (((p << 31) - var2) * 3125) // var1`
			`var1 = (self.dig_P9 * (p >> 13) * (p >> 13)) >> 25`
			`var2 = (self.dig_P8 * p) >> 19`
			`pressure = ((p + var1 + var2) >> 8) + (self.dig_P7 << 4)`

			`# humidity`
			`h = self.t_fine - 76800`
			`h = (((((raw_hum << 14) - (self.dig_H4 << 20) -`
			`(self.dig_H5 * h)) + 16384)`
			`>> 15) * (((((((h * self.dig_H6) >> 10) *`
			`(((h * self.dig_H3) >> 11) + 32768)) >> 10) +`
			`2097152) * self.dig_H2 + 8192) >> 14))`
			`h = h - (((((h >> 15) * (h >> 15)) >> 7) * self.dig_H1) >> 4)`
			`h = 0 if h < 0 else h`
			`h = 419430400 if h > 419430400 else h`
			`humidity = h >> 12`

			`if result:`
			`result[0] = temp`
			`result[1] = pressure`
			`result[2] = humidity`
			`return result`

			`return array("i", (temp, pressure, humidity))`

			`@property`
			`def values(self):`
			`""" human readable values """`

			`t, p, h = self.read_compensated_data()`

			`p = p // 256`
			`pi = p // 100`
			`pd = p - pi * 100`

			`hi = h // 1024`
			`hd = h * 100 // 1024 - hi * 100`
			`return ("{}C".format(t / 100), "{}.{:02d}hPa".format(pi, pd),`
			`"{}.{:02d}%".format(hi, hd))`