Clemens Valens
/
bme280
Driver for Bosch Sensortec BME280 combined humidity and pressure sensor
Diff: bme280.cpp
- Revision:
- 0:b16a9b34fa4c
diff -r 000000000000 -r b16a9b34fa4c bme280.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/bme280.cpp Tue Sep 06 15:17:20 2016 +0000 @@ -0,0 +1,389 @@ +/* + bme280.cpp - driver for Bosch Sensortec BME280 combined humidity and pressure sensor. + + Copyright (c) 2015 Elektor + + 26/11/2015 - CPV, Initial release. + + This library is free software; you can redistribute it and/or + modify it under the terms of the GNU Lesser General Public + License as published by the Free Software Foundation; either + version 2.1 of the License, or (at your option) any later version. + + This library is distributed in the hope that it will be useful, + but WITHOUT ANY WARRANTY; without even the implied warranty of + MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU + Lesser General Public License for more details. + + You should have received a copy of the GNU Lesser General + Public License along with this library; if not, write to the + Free Software Foundation, Inc., 59 Temple Place, Suite 330, + Boston, MA 02111-1307 USA + +*/ + +#include "bme280.h" + + +BME280::BME280(void) +{ + _i2c_address = 0; + _t_fine = 0; + _temperature = 0; + _pressure = 0; + _humidity = 0; + clearCalibrationData(); +} + + +void BME280::clearCalibrationData(void) +{ + _dig_T1 = 0; + _dig_T2 = 0; + _dig_T3 = 0; + _dig_P1 = 0; + _dig_P2 = 0; + _dig_P3 = 0; + _dig_P4 = 0; + _dig_P5 = 0; + _dig_P6 = 0; + _dig_P7 = 0; + _dig_P8 = 0; + _dig_P9 = 0; + _dig_H1 = 0; + _dig_H2 = 0; + _dig_H3 = 0; + _dig_H4 = 0; + _dig_H5 = 0; + _dig_H6 = 0; +} + + +uint8_t BME280::begin(uint8_t i2cAddress) +{ + _i2c_address = i2cAddress; + if (readId()==BME280_ID) + { + clearCalibrationData(); + readCalibrationData(); + return 0; + } + return (uint8_t)-1; +} + + +void BME280::busWrite(uint8_t *p_data, uint8_t data_size, uint8_t repeated_start) +{ + if (_i2c_address==BME280_I2C_ADDRESS1 || _i2c_address==BME280_I2C_ADDRESS2) + { + // Assume I2C bus. + i2cWrite(_i2c_address,p_data,data_size,repeated_start); + } + else + { + // Assume SPI bus. + // First byte is supposed to be the address of the register to write to, set R/~W bit to 0. + p_data[0] &= 0x7f; + spiWrite(p_data,data_size); + } +} + + +void BME280::busRead(uint8_t *p_data, uint8_t data_size) +{ + if (_i2c_address==BME280_I2C_ADDRESS1 || _i2c_address==BME280_I2C_ADDRESS2) + { + // Assume I2C bus. + i2cRead(_i2c_address,p_data,data_size); + } + else + { + // Assume SPI bus. + // First byte is supposed to be the address of the register to write to, set R/~W bit to 1. + p_data[0] |= 0x80; + spiRead(p_data,data_size); + } +} + + +uint8_t BME280::readUint8(uint8_t reg) +{ + uint8_t data; + busWrite(®,1,1); // Use repeated start. + busRead(&data,1); // Read one byte. + return data; +} + + +uint16_t BME280::readUint16(uint8_t reg) +{ + uint8_t data[2]; + uint16_t value; + busWrite(®,1,1); // Use repeated start. + busRead(data,2); // Read two bytes. + // Process as little endian, which is the case for calibration data. + value = data[1]; + value = (value<<8) | data[0]; + return value; +} + + +void BME280::readCalibrationData(void) +{ + _dig_T1 = readUint16(BME280_CAL_T1); + _dig_T2 = (int16_t) readUint16(BME280_CAL_T2); + _dig_T3 = (int16_t) readUint16(BME280_CAL_T3); + _dig_P1 = readUint16(BME280_CAL_P1); + _dig_P2 = (int16_t) readUint16(BME280_CAL_P2); + _dig_P3 = (int16_t) readUint16(BME280_CAL_P3); + _dig_P4 = (int16_t) readUint16(BME280_CAL_P4); + _dig_P5 = (int16_t) readUint16(BME280_CAL_P5); + _dig_P6 = (int16_t) readUint16(BME280_CAL_P6); + _dig_P7 = (int16_t) readUint16(BME280_CAL_P7); + _dig_P8 = (int16_t) readUint16(BME280_CAL_P8); + _dig_P9 = (int16_t) readUint16(BME280_CAL_P9); + _dig_H1 = readUint8(BME280_CAL_H1); + _dig_H2 = (int16_t) readUint16(BME280_CAL_H2); + _dig_H3 = readUint8(BME280_CAL_H3); + // H4 & H5 share a byte. + uint8_t temp1 = readUint8(BME280_CAL_H4); + uint8_t temp2 = readUint8(BME280_CAL_H45); + uint8_t temp3 = readUint8(BME280_CAL_H5); + _dig_H4 = (temp1<<4) | (temp2&0x0f); + _dig_H5 = (temp3<<4) | (temp2>>4); + _dig_H6 = (int8_t) readUint8(BME280_CAL_H6); +} + + +uint8_t BME280::readFrom(uint8_t reg, uint8_t data_size, uint8_t *p_data) +{ + // Set start address to read from. + busWrite(®,1,1); // Use repeated start. + // Now read the requested number of bytes. + busRead(p_data,data_size); + return data_size; +} + + +void BME280::read(void) +{ + // Get all the measurements in one burst (recommended). + uint8_t data[BME280_MEASUREMENT_SIZE]; + readFrom(BME280_MEASUREMENT_REGISTER,BME280_MEASUREMENT_SIZE,data); + // We assume Normal mode, so it is not necessary to reissue a Forced mode command here. + + // Process data. + int32_t p = assembleRawValue(&data[0],1); + int32_t t = assembleRawValue(&data[3],1); + int32_t h = assembleRawValue(&data[6],0); + + _temperature = compensateTemperature(t); // First call this before calling the other compensate functions. + _pressure = compensatePressure(p); // Uses value calculated by compensateTemperature. + _humidity = compensateHumidity(h); // Uses value calculated by compensateTemperature. +} + + +int32_t BME280::assembleRawValue(uint8_t *p_data, uint8_t has_xlsb) +{ + // Needed to decode sensor data. + uint32_t value = p_data[0]; + value <<= 8; + value |= p_data[1]; + if (has_xlsb!=0) + { + value <<= 4; + value |= (p_data[2]>>4); + } + return (int32_t) value; +} + + +void BME280::writeControlRegisters(uint8_t osrs_t, uint8_t osrs_p, uint8_t osrs_h, uint8_t mode) +{ + uint8_t data[2]; + data[0] = BME280_CTRL_HUM_REGISTER; + data[1] = (osrs_h&0x07); + busWrite(data,2,0); + // Writing CTRL_MEAS validates previous write to CTRL_HUM. + data[0] = BME280_CTRL_MEAS_REGISTER; + data[1] = ((osrs_t&0x07)<<5) | ((osrs_p&0x07)<<2) | (mode&0x03); + busWrite(data,2,0); +} + + +void BME280::writeConfigRegister(uint8_t t_sb, uint8_t filter, uint8_t spi) +{ + uint8_t data[2]; + data[0] = BME280_CONFIG_REGISTER; + data[1] = ((t_sb&0x07)<<5) | ((filter&0x07)<<2) | (spi&0x01); + busWrite(data,2,0); +} + + +void BME280::reset(void) +{ + uint8_t data[2] = { BME280_RESET_REGISTER, BME280_RESET }; + busWrite(data,2,0); +} + + +uint8_t BME280::readId(void) +{ + return readUint8(BME280_ID_REGISTER); +} + + +#if BME280_ALLOW_FLOAT!=0 + +// From the driver by Bosch Sensortec + +//! +// @brief Reads actual temperature from uncompensated temperature +// @note returns the value in Degree centigrade +// @note Output value of "51.23" equals 51.23 DegC. +// +// @param adc_T : value of uncompensated temperature +// +// @return Return the actual temperature in floating point +// +temperature_t BME280::compensateTemperature(int32_t adc_T) +{ + double v_x1_u32; + double v_x2_u32; + double temperature; + + v_x1_u32 = (((double)adc_T) / 16384.0 - ((double)_dig_T1) / 1024.0) * ((double)_dig_T2); + v_x2_u32 = ((((double)adc_T) / 131072.0 - ((double)_dig_T1) / 8192.0) * (((double)adc_T) / 131072.0 - ((double)_dig_T1) / 8192.0)) * ((double)_dig_T3); + _t_fine = (int32_t)(v_x1_u32 + v_x2_u32); + temperature = (v_x1_u32 + v_x2_u32) / 5120.0; + return temperature; +} + + +//! +// @brief Reads actual pressure from uncompensated pressure +// @note Returns pressure in Pa as double. +// @note Output value of "96386.2" +// equals 96386.2 Pa = 963.862 hPa. +// +// @param adc_P : value of uncompensated pressure +// +// @return Return the actual pressure in floating point +// +pressure_t BME280::compensatePressure(int32_t adc_P) +{ + double v_x1_u32; + double v_x2_u32; + double pressure; + + v_x1_u32 = ((double)_t_fine / 2.0) - 64000.0; + v_x2_u32 = v_x1_u32 * v_x1_u32 * ((double)_dig_P6) / 32768.0; + v_x2_u32 = v_x2_u32 + v_x1_u32 * ((double)_dig_P5) * 2.0; + v_x2_u32 = (v_x2_u32 / 4.0) + (((double)_dig_P4) * 65536.0); + v_x1_u32 = (((double)_dig_P3) * v_x1_u32 * v_x1_u32 / 524288.0 + ((double)_dig_P2) * v_x1_u32) / 524288.0; + v_x1_u32 = (1.0 + v_x1_u32 / 32768.0) * ((double)_dig_P1); + pressure = 1048576.0 - (double)adc_P; + // Avoid exception caused by division by zero. + if (v_x1_u32 != 0) pressure = (pressure - (v_x2_u32 / 4096.0)) * 6250.0 / v_x1_u32; + else return 0; + v_x1_u32 = ((double)_dig_P9) * pressure * pressure / 2147483648.0; + v_x2_u32 = pressure * ((double)_dig_P8) / 32768.0; + pressure = pressure + (v_x1_u32 + v_x2_u32 + ((double)_dig_P7)) / 16.0; + + return pressure; +} + + +//! +// @brief Reads actual humidity from uncompensated humidity +// @note returns the value in relative humidity (%rH) +// @note Output value of "42.12" equals 42.12 %rH +// +// @param adc_H : value of uncompensated humidity +// +// @return Return the actual humidity in floating point +// +humidity_t BME280::compensateHumidity(int32_t adc_H) +{ + double var_h; + + var_h = (((double)_t_fine) - 76800.0); + if (var_h != 0) + { + var_h = (adc_H - (((double)_dig_H4) * 64.0 + ((double)_dig_H5) / 16384.0 * var_h)) * + (((double)_dig_H2) / 65536.0 * (1.0 + ((double) _dig_H6) / 67108864.0 * + var_h * (1.0 + ((double)_dig_H3) / 67108864.0 * var_h))); + } + else return 0; + var_h = var_h * (1.0 - ((double)_dig_H1)*var_h / 524288.0); + if (var_h > 100.0) var_h = 100.0; + else if (var_h < 0.0) var_h = 0.0; + return var_h; +} + +#else /* BME280_ALLOW_FLOAT */ + +// From the datasheet. +// Returns temperature in DegC, resolution is 0.01 DegC. Output value of 5123 equals 51.23 DegC. +// _t_fine carries fine temperature as "global" value. +temperature_t BME280::compensateTemperature(int32_t adc_T) +{ + int32_t var1, var2, T; + var1 = ((((adc_T>>3) - ((int32_t)_dig_T1<<1))) * ((int32_t)_dig_T2)) >> 11; + var2 = (((((adc_T>>4) - ((int32_t)_dig_T1)) * ((adc_T>>4) - ((int32_t)_dig_T1))) >> 12) * ((int32_t)_dig_T3)) >> 14; + _t_fine = var1 + var2; + T = (_t_fine * 5 + 128) >> 8; + return T; +} + + +// From the datasheet. +// Returns pressure in Pa as unsigned 32 bit integer. Output value of 96386 equals 96386 Pa = 963.86 hPa +pressure_t BME280::compensatePressure(int32_t adc_P) +{ + int32_t var1, var2; + uint32_t p; + var1 = (((int32_t)_t_fine)>>1) - (int32_t)64000; + var2 = (((var1>>2) * (var1>>2)) >> 11 ) * ((int32_t)_dig_P6); + var2 = var2 + ((var1*((int32_t)_dig_P5))<<1); + var2 = (var2>>2)+(((int32_t)_dig_P4)<<16); + var1 = (((_dig_P3 * (((var1>>2) * (var1>>2)) >> 13 )) >> 3) + ((((int32_t)_dig_P2) * var1)>>1))>>18; + var1 =((((32768+var1))*((int32_t)_dig_P1))>>15); + if (var1 == 0) + { + return 0; // avoid exception caused by division by zero + } + p = (((uint32_t)(((int32_t)1048576)-adc_P)-(var2>>12)))*3125; + if (p < 0x80000000) + { + p = (p << 1) / ((uint32_t)var1); + } + else + { + p = (p / (uint32_t)var1) * 2; + } + var1 = (((int32_t)_dig_P9) * ((int32_t)(((p>>3) * (p>>3))>>13)))>>12; + var2 = (((int32_t)(p>>2)) * ((int32_t)_dig_P8))>>13; + p = (uint32_t)((int32_t)p + ((var1 + var2 + _dig_P7) >> 4)); + return p; +} + + +// From the datasheet. +// Returns humidity in %RH as unsigned 32 bit integer in Q22.10 format (22 integer and 10 fractional bits). +// Output value of 47445 represents 47445/1024 = 46.333 %RH +humidity_t BME280::compensateHumidity(int32_t adc_H) +{ + int32_t v_x1_u32r; + v_x1_u32r = (_t_fine - ((int32_t)76800)); + v_x1_u32r = (((((adc_H << 14) - (((int32_t)_dig_H4) << 20) - (((int32_t)_dig_H5) * v_x1_u32r)) + + ((int32_t)16384)) >> 15) * (((((((v_x1_u32r * ((int32_t)_dig_H6)) >> 10) * (((v_x1_u32r * + ((int32_t)_dig_H3)) >> 11) + ((int32_t)32768))) >> 10) + ((int32_t)2097152)) * + ((int32_t)_dig_H2) + 8192) >> 14)); + v_x1_u32r = (v_x1_u32r - (((((v_x1_u32r >> 15) * (v_x1_u32r >> 15)) >> 7) * ((int32_t)_dig_H1)) >> 4)); + v_x1_u32r = (v_x1_u32r < 0 ? 0 : v_x1_u32r); + v_x1_u32r = (v_x1_u32r > 419430400 ? 419430400 : v_x1_u32r); + return (uint32_t)(v_x1_u32r>>12); +} + +#endif /* BME280_ALLOW_FLOAT */