ocoge/local_modules/@ocogeclub/bme280/BME280.js

'use strict';

this.pig = null;
this.pi = null;

this.i2cBusNo = null;
this.i2cAddress = null;
this.i2cHand = null;

this.I2C_ADDRESS_B = 0x76;
this.I2C_ADDRESS_A = 0x77;
this.CHIP_ID = 0x58;

this.REGISTER_DIG_T1 = 0x88;
this.REGISTER_DIG_T2 = 0x8A;
this.REGISTER_DIG_T3 = 0x8C;

this.REGISTER_DIG_P1 = 0x8E;
this.REGISTER_DIG_P2 = 0x90;
this.REGISTER_DIG_P3 = 0x92;
this.REGISTER_DIG_P4 = 0x94;
this.REGISTER_DIG_P5 = 0x96;
this.REGISTER_DIG_P6 = 0x98;
this.REGISTER_DIG_P7 = 0x9A;
this.REGISTER_DIG_P8 = 0x9C;
this.REGISTER_DIG_P9 = 0x9E;

this.REGISTER_DIG_H1 = 0xA1;
this.REGISTER_DIG_H2 = 0xE1;
this.REGISTER_DIG_H3 = 0xE3;
this.REGISTER_DIG_H4 = 0xE4;
this.REGISTER_DIG_H5 = 0xE5;
this.REGISTER_DIG_H6 = 0xE7;

this.REGISTER_CHIPID = 0xD0;
this.REGISTER_RESET = 0xE0;

this.REGISTER_CONTROL_HUM = 0xF2;
this.REGISTER_CONTROL = 0xF4;
this.REGISTER_PRESSURE_DATA = 0xF7;
this.REGISTER_TEMP_DATA = 0xFA;
this.REGISTER_HUMIDITY_DATA = 0xFD;

exports.init = async (options) => {
  this.pig = require('@ocogeclub/pigpio')
  // console.log('pig= ' + this.pig)
  this.pi = await this.pig._pigpio_start('', '');
  // console.log('pi= ' + this.pi)
  // this.pi = require('@ocogeclub/lgpio');

  this.i2cBusNo = (options && options.hasOwnProperty('i2cBusNo')) ? options.i2cBusNo : 1;
  this.i2cAddress = (options && options.hasOwnProperty('i2cAddress')) ? options.i2cAddress : this.BME280_DEFAULT_I2C_ADDRESS();
  this.i2cHand = await this.pig._i2c_open(this.pi, this.i2cBusNo, this.i2cAddress);
  // console.log('i2cHand= ' + this.i2cHand)
  // this.i2cHand = this.pi._i2c_open(this.i2cBusNo, this.i2cAddress);

  let r;
  r = await this.pig._i2c_write_byte_data(this.pi, this.i2cHand, this.REGISTER_CHIPID, 0);
  // r = this.pi._i2c_write_byte_data(this.i2cHand, this.REGISTER_CHIPID, 0);
  if (r < 0) return r;
  let chipId = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_CHIPID);
  // let chipId = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_CHIPID);
  if (chipId !== this.CHIP_ID_BME280() &&
    chipId !== this.CHIP_ID1_BMP280() &&
    chipId !== this.CHIP_ID2_BMP280() &&
    chipId !== this.CHIP_ID3_BMP280()) {
    return `Unexpected BMx280 chip ID: 0x${chipId.toString(16).toUpperCase()}`;
  }
  // console.log(`Found BMx280 chip ID 0x${chipId.toString(16).toUpperCase()} on bus i2c-${this.i2cBusNo}, address 0x${this.i2cAddress.toString(16).toUpperCase()}`);
  await this.loadCalibration(async (err) => {
    if (err) {
      return err;
    }
    // Humidity 16x oversampling
    //
    let r = await this.pig._i2c_write_byte_data(this.pi, this.i2cHand, this.REGISTER_CONTROL_HUM, 0b00000101);
    // let r = this.pi._i2c_write_byte_data(this.i2cHand, this.REGISTER_CONTROL_HUM, 0b00000101);
    if (r < 0) return `Humidity 16x oversampling error: ${r}`;
    // Temperture/pressure 16x oversampling, normal mode
    //
    r = await this.pig._i2c_write_byte_data(this.pi, this.i2cHand, this.REGISTER_CONTROL, 0b10110111);
    // r = this.pi._i2c_write_byte_data(this.i2cHand, this.REGISTER_CONTROL, 0b10110111);
    if (r < 0) return `Temperture/pressure 16x oversampling error: ${r}`;

    return 0;
  });
}

// reset()
//
// Perform a power-on reset procedure. You will need to call init() following a reset()
//
exports.reset = async () => {
  const POWER_ON_RESET_CMD = 0xB6;
  let r = await this.pig._i2c_write_byte_data(this.pi, this.i2cHand, this.REGISTER_RESET, POWER_ON_RESET_CMD);
  // let r = this.pi._i2c_write_byte_data(this.i2cHand, this.REGISTER_RESET, POWER_ON_RESET_CMD);
  if (r < 0) return `cannot power-on reset: ${r}`;
  else return 0;
}

// cancel()
//
// Cancels the sensor and releases resources.
//
exports.cancel = async () => {
  if (this.i2cHand >= 0) {
    await this.pig._i2c_close(this.pi, this.i2cHand);
    // this.pi._i2c_close(this.i2cHand);
    this.i2cHand = null;
    await this.pig._pigpio_stop(this.pi);
    this.pi = null;
  }
}

exports.readSensorData = async () => {
  if (!this.cal) {
    return 'You must first call bme280.init()';
  }

  // Grab temperature, humidity, and pressure in a single read
  //
  let buffer = await this.pig._i2c_read_i2c_block_data(this.pi, this.i2cHand, this.REGISTER_PRESSURE_DATA, 8);
  // let buffer = this.pi._i2c_read_i2c_block_data(this.i2cHand, this.REGISTER_PRESSURE_DATA, 8);
  if (!buffer) return `couldn't grab data`;
  // Temperature (temperature first since we need t_fine for pressure and humidity)
  //
  let adc_T = this.uint20(buffer[3], buffer[4], buffer[5]);
  let tvar1 = ((((adc_T >> 3) - (this.cal.dig_T1 << 1))) * this.cal.dig_T2) >> 11;
  let tvar2 = (((((adc_T >> 4) - this.cal.dig_T1) * ((adc_T >> 4) - this.cal.dig_T1)) >> 12) * this.cal.dig_T3) >> 14;
  let t_fine = tvar1 + tvar2;

  let temperature_C = ((t_fine * 5 + 128) >> 8) / 100;

  // Pressure
  //
  let adc_P = this.uint20(buffer[0], buffer[1], buffer[2]);
  let pvar1 = t_fine / 2 - 64000;
  let pvar2 = pvar1 * pvar1 * this.cal.dig_P6 / 32768;
  pvar2 = pvar2 + pvar1 * this.cal.dig_P5 * 2;
  pvar2 = pvar2 / 4 + this.cal.dig_P4 * 65536;
  pvar1 = (this.cal.dig_P3 * pvar1 * pvar1 / 524288 + this.cal.dig_P2 * pvar1) / 524288;
  pvar1 = (1 + pvar1 / 32768) * this.cal.dig_P1;

  let pressure_hPa = 0;

  if (pvar1 !== 0) {
    let p = 1048576 - adc_P;
    p = ((p - pvar2 / 4096) * 6250) / pvar1;
    pvar1 = this.cal.dig_P9 * p * p / 2147483648;
    pvar2 = p * this.cal.dig_P8 / 32768;
    p = p + (pvar1 + pvar2 + this.cal.dig_P7) / 16;

    pressure_hPa = p / 100;
  }

  // Humidity (available on the BME280, will be zero on the BMP280 since it has no humidity sensor)
  //
  let adc_H = this.uint16(buffer[6], buffer[7]);

  let h = t_fine - 76800;
  h = (adc_H - (this.cal.dig_H4 * 64 + this.cal.dig_H5 / 16384 * h)) *
    (this.cal.dig_H2 / 65536 * (1 + this.cal.dig_H6 / 67108864 * h * (1 + this.cal.dig_H3 / 67108864 * h)));
  h = h * (1 - this.cal.dig_H1 * h / 524288);

  let humidity = (h > 100) ? 100 : (h < 0 ? 0 : h);

  return {
    temperature_C: temperature_C,
    humidity: humidity,
    pressure_hPa: pressure_hPa
  };
}

exports.loadCalibration = async (callback) => {
  let buffer = await this.pig._i2c_read_i2c_block_data(this.pi, this.i2cHand, this.REGISTER_DIG_T1, 24);
  // let buffer = this.pi._i2c_read_i2c_block_data(this.i2cHand, this.REGISTER_DIG_T1, 24);
  // for (let i = 0; i < 24; i++) console.log(parseInt(buffer[i], 16));
  if (buffer) {
    let h1 = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_DIG_H1);
    let h2 = await this.pig._i2c_read_word_data(this.pi, this.i2cHand, this.REGISTER_DIG_H2);
    let h3 = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_DIG_H3);
    let h4 = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_DIG_H4);
    let h5 = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_DIG_H5);
    let h5_1 = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_DIG_H5 + 1);
    let h6 = await this.pig._i2c_read_byte_data(this.pi, this.i2cHand, this.REGISTER_DIG_H6);
    // let h1 = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_DIG_H1);
    // let h2 = this.pi._i2c_read_word_data(this.i2cHand, this.REGISTER_DIG_H2);
    // let h3 = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_DIG_H3);
    // let h4 = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_DIG_H4);
    // let h5 = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_DIG_H5);
    // let h5_1 = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_DIG_H5 + 1);
    // let h6 = this.pi._i2c_read_byte_data(this.i2cHand, this.REGISTER_DIG_H6);

    this.cal = {
      dig_T1: this.uint16(buffer[1], buffer[0]),
      dig_T2: this.int16(buffer[3], buffer[2]),
      dig_T3: this.int16(buffer[5], buffer[4]),

      dig_P1: this.uint16(buffer[7], buffer[6]),
      dig_P2: this.int16(buffer[9], buffer[8]),
      dig_P3: this.int16(buffer[11], buffer[10]),
      dig_P4: this.int16(buffer[13], buffer[12]),
      dig_P5: this.int16(buffer[15], buffer[14]),
      dig_P6: this.int16(buffer[17], buffer[16]),
      dig_P7: this.int16(buffer[19], buffer[18]),
      dig_P8: this.int16(buffer[21], buffer[20]),
      dig_P9: this.int16(buffer[23], buffer[22]),

      dig_H1: h1,
      dig_H2: h2,
      dig_H3: h3,
      dig_H4: (h4 << 4) | (h5 & 0xF),
      dig_H5: (h5_1 << 4) | (h5 >> 4),
      dig_H6: h6
    };

    // console.log('BME280 cal = ' + JSON.stringify(this.cal, null, 2));
    await callback();
  }
}

exports.BME280_DEFAULT_I2C_ADDRESS = () => {
  return 0x77;
}

exports.CHIP_ID1_BMP280 = () => {
  return 0x56;
}

exports.CHIP_ID2_BMP280 = () => {
  return 0x57;
}

exports.CHIP_ID3_BMP280 = () => {
  return 0x58;
}

exports.CHIP_ID_BME280 = () => {
  return 0x60;
}

exports.int16 = (msb, lsb) => {
  let val = this.uint16(msb, lsb);
  return val > 32767 ? (val - 65536) : val;
}

exports.uint16 = (msb, lsb) => {
  return msb << 8 | lsb;
}

exports.uint20 = (msb, lsb, xlsb) => {
  return ((msb << 8 | lsb) << 8 | xlsb) >> 4;
}

exports.convertCelciusToFahrenheit = (c) => {
  return c * 9 / 5 + 32;
}

exports.convertHectopascalToInchesOfMercury = (hPa) => {
  return hPa * 0.02952998751;
}

exports.convertMetersToFeet = (m) => {
  return m * 3.28084;
}

exports.calculateHeatIndexCelcius = (temperature_C, humidity) => {
  return -8.784695 + 1.61139411 * temperature_C + 2.33854900 * humidity +
    -0.14611605 * temperature_C * humidity + -0.01230809 * Math.pow(temperature_C, 2) +
    -0.01642482 * Math.pow(humidity, 2) + 0.00221173 * Math.pow(temperature_C, 2) * humidity +
    0.00072546 * temperature_C * Math.pow(humidity, 2) +
    -0.00000358 * Math.pow(temperature_C, 2) * Math.pow(humidity, 2);
}

exports.calculateDewPointCelcius = (temperature_C, humidity) => {
  return 243.04 * (Math.log(humidity / 100.0) + ((17.625 * temperature_C) / (243.04 + temperature_C))) /
    (17.625 - Math.log(humidity / 100.0) - ((17.625 * temperature_C) / (243.04 + temperature_C)));
}

exports.calculateAltitudeMeters = (pressure_hPa, seaLevelPressure_hPa) => {
  if (!seaLevelPressure_hPa) {
    seaLevelPressure_hPa = 1013.25;
  }

  return (1.0 - Math.pow(pressure_hPa / seaLevelPressure_hPa, (1 / 5.2553))) * 145366.45 * 0.3048;
}


/*
 * This code was forked from skylarstein's bme280-sensor: https://github.com/skylarstein/bme280-sensor
 */