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RIOT/drivers/bmp180/bmp180.c 7.92 KB
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  /*
   * Copyright (C) 2016 Inria
   *
   * This file is subject to the terms and conditions of the GNU Lesser
   * General Public License v2.1. See the file LICENSE in the top level
   * directory for more details.
   */
  
  /**
   * @ingroup     drivers_bmp180
   * @{
   *
   * @file
   * @brief       Device driver implementation for the BMP180/BMP085 temperature and pressure sensor.
   *
   * @author      Alexandre Abadie <alexandre.abadie@inria.fr>
   *
   * @}
   */
  
  #include <math.h>
  
  #include "log.h"
  #include "bmp180.h"
  #include "bmp180_internals.h"
  #include "bmp180_params.h"
  #include "periph/i2c.h"
  #include "xtimer.h"
  
  #define ENABLE_DEBUG        (0)
  #include "debug.h"
  
  #define DEV_I2C      (dev->params.i2c_dev)
  #define DEV_ADDR     (dev->params.i2c_addr)
  #define OVERSAMPLING (dev->params.oversampling)
  
  /* Internal function prototypes */
  static int _read_ut(const bmp180_t *dev, int32_t *ut);
  static int _read_up(const bmp180_t *dev, int32_t *up);
  static int _compute_b5(const bmp180_t *dev, int32_t ut, int32_t *b5);
  
  /*---------------------------------------------------------------------------*
   *                          BMP180 Core API                                 *
   *---------------------------------------------------------------------------*/
  
  int bmp180_init(bmp180_t *dev, const bmp180_params_t *params)
  {
      dev->params = *params;
  
      /* Clamp oversampling mode */
      if (OVERSAMPLING > BMP180_ULTRAHIGHRES) {
          OVERSAMPLING = BMP180_ULTRAHIGHRES;
      }
  
      /* Initialize I2C interface */
      if (i2c_init_master(DEV_I2C, I2C_SPEED_NORMAL)) {
          DEBUG("[Error] I2C device not enabled\n");
          return -BMP180_ERR_NOI2C;
      }
  
      /* Acquire exclusive access */
      i2c_acquire(DEV_I2C);
  
      /* Check sensor ID */
      uint8_t checkid;
      i2c_read_reg(DEV_I2C, DEV_ADDR, BMP180_REGISTER_ID, &checkid);
      if (checkid != 0x55) {
          DEBUG("[Error] Wrong device ID\n");
          i2c_release(DEV_I2C);
          return -BMP180_ERR_NODEV;
      }
  
      /* adding delay before reading calibration values to avoid timing issues */
      xtimer_usleep(BMP180_ULTRALOWPOWER_DELAY);
  
      uint8_t buffer[22] = {0};
      /* Read calibration values, using contiguous register addresses */
      if (i2c_read_regs(DEV_I2C, DEV_ADDR, BMP180_CALIBRATION_AC1, buffer, 22) < 0) {
          DEBUG("[Error] Cannot read calibration registers.\n");
          i2c_release(DEV_I2C);
          return -BMP180_ERR_NOCAL;
      }
      dev->calibration.ac1 = (int16_t)(buffer[0] << 8)   | buffer[1];
      dev->calibration.ac2 = (int16_t)(buffer[2] << 8)   | buffer[3];
      dev->calibration.ac3 = (int16_t)(buffer[4] << 8)   | buffer[4];
      dev->calibration.ac4 = (uint16_t)(buffer[6] << 8)  | buffer[7];
      dev->calibration.ac5 = (uint16_t)(buffer[8] << 8)  | buffer[9];
      dev->calibration.ac6 = (uint16_t)(buffer[10] << 8) | buffer[11];
      dev->calibration.b1  = (int16_t)(buffer[12] << 8)  | buffer[13];
      dev->calibration.b2  = (int16_t)(buffer[14] << 8)  | buffer[15];
      dev->calibration.mb  = (int16_t)(buffer[16] << 8)  | buffer[17];
      dev->calibration.mc  = (int16_t)(buffer[18] << 8)  | buffer[19];
      dev->calibration.md  = (int16_t)(buffer[20] << 8)  | buffer[21];
  
      /* Release I2C device */
      i2c_release(DEV_I2C);
  
      DEBUG("AC1: %i\n", (int)dev->calibration.ac1);
      DEBUG("AC2: %i\n", (int)dev->calibration.ac2);
      DEBUG("AC3: %i\n", (int)dev->calibration.ac3);
      DEBUG("AC4: %i\n", (int)dev->calibration.ac4);
      DEBUG("AC5: %i\n", (int)dev->calibration.ac5);
      DEBUG("AC6: %i\n", (int)dev->calibration.ac6);
      DEBUG("B1: %i\n",  (int)dev->calibration.b1);
      DEBUG("B2: %i\n",  (int)dev->calibration.b2);
      DEBUG("MB: %i\n",  (int)dev->calibration.mb);
      DEBUG("MC: %i\n",  (int)dev->calibration.mc);
      DEBUG("MD: %i\n",  (int)dev->calibration.md);
      return 0;
  }
  
  int16_t bmp180_read_temperature(const bmp180_t *dev)
  {
      int32_t ut, b5;
      /* Acquire exclusive access */
      i2c_acquire(DEV_I2C);
  
      /* Read uncompensated value */
      _read_ut(dev, &ut);
  
      /* Release I2C device */
      i2c_release(DEV_I2C);
  
      /* Compute true temperature value following datasheet formulas */
      _compute_b5(dev, ut, &b5);
  
      return (int16_t)((b5 + 8) >> 4);
  }
  
  uint32_t bmp180_read_pressure(const bmp180_t *dev)
  {
      int32_t ut = 0, up = 0, x1, x2, x3, b3, b5, b6, p;
      uint32_t b4, b7;
  
      /* Acquire exclusive access */
      i2c_acquire(DEV_I2C);
  
      /* Read uncompensated values: first temperature, second pressure */
      _read_ut(dev, &ut);
      _read_up(dev, &up);
  
      /* release I2C device */
      i2c_release(DEV_I2C);
  
      /* Compute true pressure value following datasheet formulas */
      _compute_b5(dev, ut, &b5);
      b6 = b5 - 4000;
      x1 = ((int32_t)dev->calibration.b2 * ((b6 * b6) >> 12)) >> 11;
      x2 = ((int32_t)dev->calibration.ac2 * b6) >> 11;
      x3 = x1 + x2;
      b3 = ((((int32_t)dev->calibration.ac1*4 + x3) << OVERSAMPLING) + 2) >> 2;
      x1 = ((int32_t)dev->calibration.ac3 * b6) >> 13;
      x2 = ((int32_t)dev->calibration.b1 * (b6 * b6) >> 12) >> 16;
      x3 = ((x1 + x2) + 2) >> 2;
      b4 = (int32_t)dev->calibration.ac4 * (uint32_t)(x3+32768) >> 15;
      b7 = ((uint32_t)up - b3) * (uint32_t)(50000UL >> OVERSAMPLING);
      if (b7 < 0x80000000) {
          p = (b7 * 2) / b4;
      }
      else {
          p = (b7 / b4) * 2;
      }
  
      x1 = (p >> 8) * (p >> 8);
      x1 = (x1 * 3038) >> 16;
      x2 = (-7357 * p) >> 16;
  
      return (uint32_t)(p + ((x1 + x2 + 3791) >> 4));
  }
  
  int16_t bmp180_altitude(const bmp180_t *dev, uint32_t pressure_0)
  {
      uint32_t p = bmp180_read_pressure(dev);
  
      return (int16_t)(44330.0 * (1.0 - pow((double)p / pressure_0, 0.1903)));;
  }
  
  uint32_t bmp180_sealevel_pressure(const bmp180_t *dev, int16_t altitude)
  {
      uint32_t p = bmp180_read_pressure(dev);
  
      return (uint32_t)((double)p / pow(1.0 - (altitude / 44330.0), 5.255));;
  }
  
  /*------------------------------------------------------------------------------------*/
  /*                                Internal functions                                  */
  /*------------------------------------------------------------------------------------*/
  
  static int _read_ut(const bmp180_t *dev, int32_t *output)
  {
      /* Read UT (Uncompsensated Temperature value) */
      uint8_t ut[2] = {0};
      uint8_t control[2] = { BMP180_REGISTER_CONTROL, BMP180_TEMPERATURE_COMMAND };
      i2c_write_bytes(DEV_I2C, DEV_ADDR, control, 2);
      xtimer_usleep(BMP180_ULTRALOWPOWER_DELAY);
      if (i2c_read_regs(DEV_I2C, DEV_ADDR, BMP180_REGISTER_DATA, ut, 2) < 0) {
          DEBUG("[Error] Cannot read uncompensated temperature.\n");
          i2c_release(DEV_I2C);
          return -1;
      }
      *output = ((uint16_t)ut[0] << 8) | ut[1];
  
      DEBUG("UT: %i\n", (int)*output);
  
      return 0;
  }
  
  static int _read_up(const bmp180_t *dev, int32_t *output)
  {
      /* Read UP (Uncompsensated Pressure value) */
      uint8_t up[3] = {0};
      uint8_t control[2] = { BMP180_REGISTER_CONTROL, BMP180_PRESSURE_COMMAND | (OVERSAMPLING & 0x3) << 6 };
      i2c_write_bytes(DEV_I2C, DEV_ADDR, control, 2);
      switch (OVERSAMPLING) {
      case BMP180_ULTRALOWPOWER:
          xtimer_usleep(BMP180_ULTRALOWPOWER_DELAY);
          break;
      case BMP180_STANDARD:
          xtimer_usleep(BMP180_STANDARD_DELAY);
          break;
      case BMP180_HIGHRES:
          xtimer_usleep(BMP180_HIGHRES_DELAY);
          break;
      case BMP180_ULTRAHIGHRES:
          xtimer_usleep(BMP180_ULTRAHIGHRES_DELAY);
          break;
      default:
          xtimer_usleep(BMP180_ULTRALOWPOWER_DELAY);
          break;
      }
      if (i2c_read_regs(DEV_I2C, DEV_ADDR, BMP180_REGISTER_DATA, up, 3) < 0) {
          DEBUG("[Error] Cannot read uncompensated pressure.\n");
          i2c_release(DEV_I2C);
          return -1;
      }
  
      *output = (((uint32_t)up[0] << 16) |
                 ((uint32_t)up[1] <<  8) | up[2]) >> (8 - OVERSAMPLING);
  
      DEBUG("UP: %i\n", (int)*output);
  
      return 0;
  }
  
  static int _compute_b5(const bmp180_t *dev, int32_t ut, int32_t *output)
  {
      int32_t x1, x2;
      x1 = (ut - dev->calibration.ac6) * dev->calibration.ac5 >> 15;
      x2 = (dev->calibration.mc << 11) / (x1 + dev->calibration.md);
  
      *output = x1 + x2;
  
      return 0;
  }