BRIX5

 ***************************************************************************/

 #include "Arduino.h"

 #include "WProgram.h"

    @brief  Instantiates a new Adafruit_BNO055 class

*/

  _sensorID = sensorID;

  _address = address;

    @brief  Sets up the HW

*/

  /* Enable I2C */

  Wire.begin();

  /* Make sure we have the right device */

  uint8_t id = read8(BNO055_CHIP_ID_ADDR);

  if(id != BNO055_ID)

  {

    delay(1000); // hold on for boot

    id = read8(BNO055_CHIP_ID_ADDR);

    if(id != BNO055_ID) {

      return false;  // still not? ok bail

    }

  }

  /* Switch to config mode (just in case since this is the default) */

  setMode(OPERATION_MODE_CONFIG);

  /* Reset */

  write8(BNO055_SYS_TRIGGER_ADDR, 0x20);

  while (read8(BNO055_CHIP_ID_ADDR) != BNO055_ID)

  {

    delay(10);

  }

  delay(50);

  /* Set to normal power mode */

  write8(BNO055_PWR_MODE_ADDR, POWER_MODE_NORMAL);

  delay(10);

  write8(BNO055_PAGE_ID_ADDR, 0);

  /* Set the output units */

  /*

  uint8_t unitsel = (0 << 7) | // Orientation = Android

                    (0 << 4) | // Temperature = Celsius

                    (0 << 2) | // Euler = Degrees

                    (1 << 1) | // Gyro = Rads

                    (0 << 0);  // Accelerometer = m/s^2

  write8(BNO055_UNIT_SEL_ADDR, unitsel);

  */

  write8(BNO055_SYS_TRIGGER_ADDR, 0x0);

  delay(10);

  /* Set the requested operating mode (see section 3.3) */

  setMode(mode);

  delay(20);

  return true;

    @brief  Puts the chip in the specified operating mode

*/

  _mode = mode;

  write8(BNO055_OPR_MODE_ADDR, _mode);

  delay(30);

    @brief  Use the external 32.768KHz crystal

*/

  adafruit_bno055_opmode_t modeback = _mode;

  /* Switch to config mode (just in case since this is the default) */

  setMode(OPERATION_MODE_CONFIG);

  delay(25);

  write8(BNO055_PAGE_ID_ADDR, 0);

  if (usextal) {

    write8(BNO055_SYS_TRIGGER_ADDR, 0x80);

  } else {

    write8(BNO055_SYS_TRIGGER_ADDR, 0x00);

  }

  delay(10);

  /* Set the requested operating mode (see section 3.3) */

  setMode(modeback);

  delay(20);

    @brief  Gets the latest system status info

*/

  write8(BNO055_PAGE_ID_ADDR, 0);

  /* System Status (see section 4.3.58)

     ---------------------------------

     0 = Idle

     1 = System Error

     2 = Initializing Peripherals

     3 = System Iniitalization

     4 = Executing Self-Test

     5 = Sensor fusio algorithm running

     6 = System running without fusion algorithms */

  if (system_status != 0)

    *system_status    = read8(BNO055_SYS_STAT_ADDR);

  /* Self Test Results (see section )

     --------------------------------

     1 = test passed, 0 = test failed

     Bit 0 = Accelerometer self test

     Bit 1 = Magnetometer self test

     Bit 2 = Gyroscope self test

     Bit 3 = MCU self test

     0x0F = all good! */

  if (self_test_result != 0)

    *self_test_result = read8(BNO055_SELFTEST_RESULT_ADDR);

  /* System Error (see section 4.3.59)

     ---------------------------------

     0 = No error

     1 = Peripheral initialization error

     2 = System initialization error

     3 = Self test result failed

     4 = Register map value out of range

     5 = Register map address out of range

     6 = Register map write error

     7 = BNO low power mode not available for selected operat ion mode

     8 = Accelerometer power mode not available

     9 = Fusion algorithm configuration error

     A = Sensor configuration error */

  if (system_error != 0)

    *system_error     = read8(BNO055_SYS_ERR_ADDR);

  delay(200);

    @brief  Gets the chip revision numbers

*/

  uint8_t a, b;

  memset(info, 0, sizeof(adafruit_bno055_rev_info_t));

  /* Check the accelerometer revision */

  info->accel_rev = read8(BNO055_ACCEL_REV_ID_ADDR);

  /* Check the magnetometer revision */

  info->mag_rev   = read8(BNO055_MAG_REV_ID_ADDR);

  /* Check the gyroscope revision */

  info->gyro_rev  = read8(BNO055_GYRO_REV_ID_ADDR);

  /* Check the SW revision */

  info->bl_rev    = read8(BNO055_BL_REV_ID_ADDR);

  a = read8(BNO055_SW_REV_ID_LSB_ADDR);

  b = read8(BNO055_SW_REV_ID_MSB_ADDR);

  info->sw_rev = (((uint16_t)b) << 8) | ((uint16_t)a);

    @brief  Gets current calibration state.  Each value should be a uint8_t

            pointer and it will be set to 0 if not calibrated and 3 if

            fully calibrated.

*/

  uint8_t calData = read8(BNO055_CALIB_STAT_ADDR);

  if (sys != NULL) {

    *sys = (calData >> 6) & 0x03;

  }

  if (gyro != NULL) {

    *gyro = (calData >> 4) & 0x03;

  }

  if (accel != NULL) {

    *accel = (calData >> 2) & 0x03;

  }

  if (mag != NULL) {

    *mag = calData & 0x03;

  }

    @brief  Gets the temperature in degrees celsius

*/

  int8_t temp = (int8_t)(read8(BNO055_TEMP_ADDR));

  return temp;

    @brief  Gets a vector reading from the specified source

*/

  imu::Vector<3> xyz;

  uint8_t buffer[6];

  memset (buffer, 0, 6);

  int16_t x, y, z;

  x = y = z = 0;

  /* Read vector data (6 bytes) */

  readLen((adafruit_bno055_reg_t)vector_type, buffer, 6);

  x = ((int16_t)buffer[0]) | (((int16_t)buffer[1]) << 8);

  y = ((int16_t)buffer[2]) | (((int16_t)buffer[3]) << 8);

  z = ((int16_t)buffer[4]) | (((int16_t)buffer[5]) << 8);

  /* Convert the value to an appropriate range (section 3.6.4) */

  /* and assign the value to the Vector type */

  switch(vector_type)

  {

    case VECTOR_MAGNETOMETER:

      /* 1uT = 16 LSB */

      xyz[0] = ((double)x)/16.0;

      xyz[1] = ((double)y)/16.0;

      xyz[2] = ((double)z)/16.0;

      break;

    case VECTOR_GYROSCOPE:

      /* 1rps = 900 LSB */

      xyz[0] = ((double)x)/900.0;

      xyz[1] = ((double)y)/900.0;

      xyz[2] = ((double)z)/900.0;

      break;

    case VECTOR_EULER:

      /* 1 degree = 16 LSB */

      xyz[0] = ((double)x)/16.0;

      xyz[1] = ((double)y)/16.0;

      xyz[2] = ((double)z)/16.0;

      break;

    case VECTOR_ACCELEROMETER:

    case VECTOR_LINEARACCEL:

    case VECTOR_GRAVITY:

      /* 1m/s^2 = 100 LSB */

      xyz[0] = ((double)x)/100.0;

      xyz[1] = ((double)y)/100.0;

      xyz[2] = ((double)z)/100.0;

      break;

  }

  return xyz;

    @brief  Gets a quaternion reading from the specified source

*/

  uint8_t buffer[8];

  memset (buffer, 0, 8);

  int16_t x, y, z, w;

  x = y = z = w = 0;

  /* Read quat data (8 bytes) */

  readLen(BNO055_QUATERNION_DATA_W_LSB_ADDR, buffer, 8);

  w = (((uint16_t)buffer[1]) << 8) | ((uint16_t)buffer[0]);

  x = (((uint16_t)buffer[3]) << 8) | ((uint16_t)buffer[2]);

  y = (((uint16_t)buffer[5]) << 8) | ((uint16_t)buffer[4]);

  z = (((uint16_t)buffer[7]) << 8) | ((uint16_t)buffer[6]);

  /* Assign to Quaternion */

  /* See http://ae-bst.resource.bosch.com/media/products/dokumente/bno055/BST_BNO055_DS000_12~1.pdf

     3.6.5.5 Orientation (Quaternion)  */

  const double scale = (1.0 / (1<<14));

  imu::Quaternion quat(scale * w, scale * x, scale * y, scale * z);

  return quat;

    @brief  Provides the sensor_t data for this sensor

*/

  /* Clear the sensor_t object */

  memset(sensor, 0, sizeof(sensor_t));

  /* Insert the sensor name in the fixed length char array */

  strncpy (sensor->name, "BNO055", sizeof(sensor->name) - 1);

  sensor->name[sizeof(sensor->name)- 1] = 0;

  sensor->version     = 1;

  sensor->sensor_id   = _sensorID;

  sensor->type        = SENSOR_TYPE_ORIENTATION;

  sensor->min_delay   = 0;

  sensor->max_value   = 0.0F;

  sensor->min_value   = 0.0F;

  sensor->resolution  = 0.01F;

    @brief  Reads the sensor and returns the data as a sensors_event_t

*/

  /* Clear the event */

  memset(event, 0, sizeof(sensors_event_t));

  event->version   = sizeof(sensors_event_t);

  event->sensor_id = _sensorID;

  event->type      = SENSOR_TYPE_ORIENTATION;

  event->timestamp = millis();

  /* Get a Euler angle sample for orientation */

  imu::Vector<3> euler = getVector(Adafruit_BNO055::VECTOR_EULER);

  event->orientation.x = euler.x();

  event->orientation.y = euler.y();

  event->orientation.z = euler.z();

  return true;

    if (isFullyCalibrated())

    {

        adafruit_bno055_opmode_t lastMode = _mode;

        setMode(OPERATION_MODE_CONFIG);

        readLen(ACCEL_OFFSET_X_LSB_ADDR, calibData, NUM_BNO055_OFFSET_REGISTERS);

        setMode(lastMode);

        return true;

    }

    return false;

    if (isFullyCalibrated())

    {

        adafruit_bno055_opmode_t lastMode = _mode;

        setMode(OPERATION_MODE_CONFIG);

        delay(25);

        offsets_type.accel_offset_x = (read8(ACCEL_OFFSET_X_MSB_ADDR) << 8) | (read8(ACCEL_OFFSET_X_LSB_ADDR));

        offsets_type.accel_offset_y = (read8(ACCEL_OFFSET_Y_MSB_ADDR) << 8) | (read8(ACCEL_OFFSET_Y_LSB_ADDR));

        offsets_type.accel_offset_z = (read8(ACCEL_OFFSET_Z_MSB_ADDR) << 8) | (read8(ACCEL_OFFSET_Z_LSB_ADDR));

        offsets_type.gyro_offset_x = (read8(GYRO_OFFSET_X_MSB_ADDR) << 8) | (read8(GYRO_OFFSET_X_LSB_ADDR));

        offsets_type.gyro_offset_y = (read8(GYRO_OFFSET_Y_MSB_ADDR) << 8) | (read8(GYRO_OFFSET_Y_LSB_ADDR));

        offsets_type.gyro_offset_z = (read8(GYRO_OFFSET_Z_MSB_ADDR) << 8) | (read8(GYRO_OFFSET_Z_LSB_ADDR));

        offsets_type.mag_offset_x = (read8(MAG_OFFSET_X_MSB_ADDR) << 8) | (read8(MAG_OFFSET_X_LSB_ADDR));

        offsets_type.mag_offset_y = (read8(MAG_OFFSET_Y_MSB_ADDR) << 8) | (read8(MAG_OFFSET_Y_LSB_ADDR));

        offsets_type.mag_offset_z = (read8(MAG_OFFSET_Z_MSB_ADDR) << 8) | (read8(MAG_OFFSET_Z_LSB_ADDR));

        offsets_type.accel_radius = (read8(ACCEL_RADIUS_MSB_ADDR) << 8) | (read8(ACCEL_RADIUS_LSB_ADDR));

        offsets_type.mag_radius = (read8(MAG_RADIUS_MSB_ADDR) << 8) | (read8(MAG_RADIUS_LSB_ADDR));

        setMode(lastMode);

        return true;

    }

    return false;

    adafruit_bno055_opmode_t lastMode = _mode;

    setMode(OPERATION_MODE_CONFIG);

    delay(25);

    /* A writeLen() would make this much cleaner */

    write8(ACCEL_OFFSET_X_LSB_ADDR, calibData[0]);

    write8(ACCEL_OFFSET_X_MSB_ADDR, calibData[1]);

    write8(ACCEL_OFFSET_Y_LSB_ADDR, calibData[2]);

    write8(ACCEL_OFFSET_Y_MSB_ADDR, calibData[3]);

    write8(ACCEL_OFFSET_Z_LSB_ADDR, calibData[4]);

    write8(ACCEL_OFFSET_Z_MSB_ADDR, calibData[5]);

    write8(GYRO_OFFSET_X_LSB_ADDR, calibData[6]);

    write8(GYRO_OFFSET_X_MSB_ADDR, calibData[7]);

    write8(GYRO_OFFSET_Y_LSB_ADDR, calibData[8]);

    write8(GYRO_OFFSET_Y_MSB_ADDR, calibData[9]);

    write8(GYRO_OFFSET_Z_LSB_ADDR, calibData[10]);

    write8(GYRO_OFFSET_Z_MSB_ADDR, calibData[11]);

    write8(MAG_OFFSET_X_LSB_ADDR, calibData[12]);

    write8(MAG_OFFSET_X_MSB_ADDR, calibData[13]);

    write8(MAG_OFFSET_Y_LSB_ADDR, calibData[14]);

    write8(MAG_OFFSET_Y_MSB_ADDR, calibData[15]);

    write8(MAG_OFFSET_Z_LSB_ADDR, calibData[16]);

    write8(MAG_OFFSET_Z_MSB_ADDR, calibData[17]);

    write8(ACCEL_RADIUS_LSB_ADDR, calibData[18]);

    write8(ACCEL_RADIUS_MSB_ADDR, calibData[19]);

    write8(MAG_RADIUS_LSB_ADDR, calibData[20]);

    write8(MAG_RADIUS_MSB_ADDR, calibData[21]);

    setMode(lastMode);

    adafruit_bno055_opmode_t lastMode = _mode;

    setMode(OPERATION_MODE_CONFIG);

    delay(25);

    write8(ACCEL_OFFSET_X_LSB_ADDR, (offsets_type.accel_offset_x) & 0x0FF);

    write8(ACCEL_OFFSET_X_MSB_ADDR, (offsets_type.accel_offset_x >> 8) & 0x0FF);

    write8(ACCEL_OFFSET_Y_LSB_ADDR, (offsets_type.accel_offset_y) & 0x0FF);

    write8(ACCEL_OFFSET_Y_MSB_ADDR, (offsets_type.accel_offset_y >> 8) & 0x0FF);

    write8(ACCEL_OFFSET_Z_LSB_ADDR, (offsets_type.accel_offset_z) & 0x0FF);

    write8(ACCEL_OFFSET_Z_MSB_ADDR, (offsets_type.accel_offset_z >> 8) & 0x0FF);

    write8(GYRO_OFFSET_X_LSB_ADDR, (offsets_type.gyro_offset_x) & 0x0FF);

    write8(GYRO_OFFSET_X_MSB_ADDR, (offsets_type.gyro_offset_x >> 8) & 0x0FF);

    write8(GYRO_OFFSET_Y_LSB_ADDR, (offsets_type.gyro_offset_y) & 0x0FF);

    write8(GYRO_OFFSET_Y_MSB_ADDR, (offsets_type.gyro_offset_y >> 8) & 0x0FF);

    write8(GYRO_OFFSET_Z_LSB_ADDR, (offsets_type.gyro_offset_z) & 0x0FF);

    write8(GYRO_OFFSET_Z_MSB_ADDR, (offsets_type.gyro_offset_z >> 8) & 0x0FF);

    write8(MAG_OFFSET_X_LSB_ADDR, (offsets_type.mag_offset_x) & 0x0FF);

    write8(MAG_OFFSET_X_MSB_ADDR, (offsets_type.mag_offset_x >> 8) & 0x0FF);

    write8(MAG_OFFSET_Y_LSB_ADDR, (offsets_type.mag_offset_y) & 0x0FF);

    write8(MAG_OFFSET_Y_MSB_ADDR, (offsets_type.mag_offset_y >> 8) & 0x0FF);

    write8(MAG_OFFSET_Z_LSB_ADDR, (offsets_type.mag_offset_z) & 0x0FF);

    write8(MAG_OFFSET_Z_MSB_ADDR, (offsets_type.mag_offset_z >> 8) & 0x0FF);

    write8(ACCEL_RADIUS_LSB_ADDR, (offsets_type.accel_radius) & 0x0FF);

    write8(ACCEL_RADIUS_MSB_ADDR, (offsets_type.accel_radius >> 8) & 0x0FF);

    write8(MAG_RADIUS_LSB_ADDR, (offsets_type.mag_radius) & 0x0FF);

    write8(MAG_RADIUS_MSB_ADDR, (offsets_type.mag_radius >> 8) & 0x0FF);

    setMode(lastMode);

    uint8_t system, gyro, accel, mag;

    getCalibration(&system, &gyro, &accel, &mag);

    if (system < 3 || gyro < 3 || accel < 3 || mag < 3)

        return false;

    return true;

    @brief  Writes an 8 bit value over I2C

*/

  Wire.beginTransmission(_address);

  #if ARDUINO >= 100

    Wire.write((uint8_t)reg);

    Wire.write((uint8_t)value);

  #else

    Wire.send(reg);

    Wire.send(value);

  #endif

  Wire.endTransmission();

  /* ToDo: Check for error! */

  return true;

    @brief  Reads an 8 bit value over I2C

*/

byte Adafruit_BNO055::read8(adafruit_bno055_reg_t reg )

  byte value = 0;

  Wire.beginTransmission(_address);

  #if ARDUINO >= 100

    Wire.write((uint8_t)reg);

  #else

    Wire.send(reg);

  #endif

  Wire.endTransmission();

  Wire.requestFrom(_address, (byte)1);

  #if ARDUINO >= 100

    value = Wire.read();

  #else

    value = Wire.receive();

  #endif

  return value;

    @brief  Reads the specified number of bytes over I2C

*/

  Wire.beginTransmission(_address);

  #if ARDUINO >= 100

    Wire.write((uint8_t)reg);

  #else

    Wire.send(reg);

  #endif

  Wire.endTransmission();

  Wire.requestFrom(_address, (byte)len);

  for (uint8_t i = 0; i < len; i++)

  {

    #if ARDUINO >= 100

      buffer[i] = Wire.read();

    #else

      buffer[i] = Wire.receive();

    #endif

  }

  /* ToDo: Check for errors! */

  return true;

}

 ***************************************************************************/

 #include "Arduino.h"

 #include "WProgram.h"

 #include <TinyWireM.h>

 #define Wire TinyWireM

 #include <Wire.h>

    uint16_t accel_offset_x;

    uint16_t accel_offset_y;

    uint16_t accel_offset_z;

    uint16_t gyro_offset_x;

    uint16_t gyro_offset_y;

    uint16_t gyro_offset_z;

    uint16_t mag_offset_x;

    uint16_t mag_offset_y;

    uint16_t mag_offset_z;

    uint16_t accel_radius;

    uint16_t mag_radius;

  public:

    typedef enum

    {

      /* Page id register definition */

      BNO055_PAGE_ID_ADDR                                     = 0X07,

      /* PAGE0 REGISTER DEFINITION START*/

      BNO055_CHIP_ID_ADDR                                     = 0x00,

      BNO055_ACCEL_REV_ID_ADDR                                = 0x01,

      BNO055_MAG_REV_ID_ADDR                                  = 0x02,

      BNO055_GYRO_REV_ID_ADDR                                 = 0x03,

      BNO055_SW_REV_ID_LSB_ADDR                               = 0x04,

      BNO055_SW_REV_ID_MSB_ADDR                               = 0x05,

      BNO055_BL_REV_ID_ADDR                                   = 0X06,

      /* Accel data register */

      BNO055_ACCEL_DATA_X_LSB_ADDR                            = 0X08,

      BNO055_ACCEL_DATA_X_MSB_ADDR                            = 0X09,

      BNO055_ACCEL_DATA_Y_LSB_ADDR                            = 0X0A,

      BNO055_ACCEL_DATA_Y_MSB_ADDR                            = 0X0B,

      BNO055_ACCEL_DATA_Z_LSB_ADDR                            = 0X0C,

      BNO055_ACCEL_DATA_Z_MSB_ADDR                            = 0X0D,

      /* Mag data register */

      BNO055_MAG_DATA_X_LSB_ADDR                              = 0X0E,

      BNO055_MAG_DATA_X_MSB_ADDR                              = 0X0F,

      BNO055_MAG_DATA_Y_LSB_ADDR                              = 0X10,

      BNO055_MAG_DATA_Y_MSB_ADDR                              = 0X11,

      BNO055_MAG_DATA_Z_LSB_ADDR                              = 0X12,

      BNO055_MAG_DATA_Z_MSB_ADDR                              = 0X13,

      /* Gyro data registers */

      BNO055_GYRO_DATA_X_LSB_ADDR                             = 0X14,

      BNO055_GYRO_DATA_X_MSB_ADDR                             = 0X15,

      BNO055_GYRO_DATA_Y_LSB_ADDR                             = 0X16,

      BNO055_GYRO_DATA_Y_MSB_ADDR                             = 0X17,

      BNO055_GYRO_DATA_Z_LSB_ADDR                             = 0X18,

      BNO055_GYRO_DATA_Z_MSB_ADDR                             = 0X19,

      /* Euler data registers */

      BNO055_EULER_H_LSB_ADDR                                 = 0X1A,

      BNO055_EULER_H_MSB_ADDR                                 = 0X1B,

      BNO055_EULER_R_LSB_ADDR                                 = 0X1C,

      BNO055_EULER_R_MSB_ADDR                                 = 0X1D,

      BNO055_EULER_P_LSB_ADDR                                 = 0X1E,

      BNO055_EULER_P_MSB_ADDR                                 = 0X1F,

      /* Quaternion data registers */

      BNO055_QUATERNION_DATA_W_LSB_ADDR                       = 0X20,

      BNO055_QUATERNION_DATA_W_MSB_ADDR                       = 0X21,

      BNO055_QUATERNION_DATA_X_LSB_ADDR                       = 0X22,

      BNO055_QUATERNION_DATA_X_MSB_ADDR                       = 0X23,

      BNO055_QUATERNION_DATA_Y_LSB_ADDR                       = 0X24,

      BNO055_QUATERNION_DATA_Y_MSB_ADDR                       = 0X25,

      BNO055_QUATERNION_DATA_Z_LSB_ADDR                       = 0X26,

      BNO055_QUATERNION_DATA_Z_MSB_ADDR                       = 0X27,

      /* Linear acceleration data registers */

      BNO055_LINEAR_ACCEL_DATA_X_LSB_ADDR                     = 0X28,

      BNO055_LINEAR_ACCEL_DATA_X_MSB_ADDR                     = 0X29,

      BNO055_LINEAR_ACCEL_DATA_Y_LSB_ADDR                     = 0X2A,

      BNO055_LINEAR_ACCEL_DATA_Y_MSB_ADDR                     = 0X2B,

      BNO055_LINEAR_ACCEL_DATA_Z_LSB_ADDR                     = 0X2C,

      BNO055_LINEAR_ACCEL_DATA_Z_MSB_ADDR                     = 0X2D,

      /* Gravity data registers */

      BNO055_GRAVITY_DATA_X_LSB_ADDR                          = 0X2E,

      BNO055_GRAVITY_DATA_X_MSB_ADDR                          = 0X2F,

      BNO055_GRAVITY_DATA_Y_LSB_ADDR                          = 0X30,

      BNO055_GRAVITY_DATA_Y_MSB_ADDR                          = 0X31,

      BNO055_GRAVITY_DATA_Z_LSB_ADDR                          = 0X32,

      BNO055_GRAVITY_DATA_Z_MSB_ADDR                          = 0X33,

      /* Temperature data register */

      BNO055_TEMP_ADDR                                        = 0X34,

      /* Status registers */

      BNO055_CALIB_STAT_ADDR                                  = 0X35,

      BNO055_SELFTEST_RESULT_ADDR                             = 0X36,

      BNO055_INTR_STAT_ADDR                                   = 0X37,

      BNO055_SYS_CLK_STAT_ADDR                                = 0X38,

      BNO055_SYS_STAT_ADDR                                    = 0X39,

      BNO055_SYS_ERR_ADDR                                     = 0X3A,

      /* Unit selection register */

      BNO055_UNIT_SEL_ADDR                                    = 0X3B,

      BNO055_DATA_SELECT_ADDR                                 = 0X3C,

      /* Mode registers */

      BNO055_OPR_MODE_ADDR                                    = 0X3D,

      BNO055_PWR_MODE_ADDR                                    = 0X3E,

      BNO055_SYS_TRIGGER_ADDR                                 = 0X3F,

      BNO055_TEMP_SOURCE_ADDR                                 = 0X40,

      /* Axis remap registers */

      BNO055_AXIS_MAP_CONFIG_ADDR                             = 0X41,

      BNO055_AXIS_MAP_SIGN_ADDR                               = 0X42,

      /* SIC registers */

      BNO055_SIC_MATRIX_0_LSB_ADDR                            = 0X43,

      BNO055_SIC_MATRIX_0_MSB_ADDR                            = 0X44,

      BNO055_SIC_MATRIX_1_LSB_ADDR                            = 0X45,

      BNO055_SIC_MATRIX_1_MSB_ADDR                            = 0X46,

      BNO055_SIC_MATRIX_2_LSB_ADDR                            = 0X47,

      BNO055_SIC_MATRIX_2_MSB_ADDR                            = 0X48,

      BNO055_SIC_MATRIX_3_LSB_ADDR                            = 0X49,

      BNO055_SIC_MATRIX_3_MSB_ADDR                            = 0X4A,

      BNO055_SIC_MATRIX_4_LSB_ADDR                            = 0X4B,

      BNO055_SIC_MATRIX_4_MSB_ADDR                            = 0X4C,

      BNO055_SIC_MATRIX_5_LSB_ADDR                            = 0X4D,

      BNO055_SIC_MATRIX_5_MSB_ADDR                            = 0X4E,

      BNO055_SIC_MATRIX_6_LSB_ADDR                            = 0X4F,

      BNO055_SIC_MATRIX_6_MSB_ADDR                            = 0X50,

      BNO055_SIC_MATRIX_7_LSB_ADDR                            = 0X51,

      BNO055_SIC_MATRIX_7_MSB_ADDR                            = 0X52,

      BNO055_SIC_MATRIX_8_LSB_ADDR                            = 0X53,

      BNO055_SIC_MATRIX_8_MSB_ADDR                            = 0X54,

      /* Accelerometer Offset registers */

      ACCEL_OFFSET_X_LSB_ADDR                                 = 0X55,

      ACCEL_OFFSET_X_MSB_ADDR                                 = 0X56,

      ACCEL_OFFSET_Y_LSB_ADDR                                 = 0X57,

      ACCEL_OFFSET_Y_MSB_ADDR                                 = 0X58,

      ACCEL_OFFSET_Z_LSB_ADDR                                 = 0X59,

      ACCEL_OFFSET_Z_MSB_ADDR                                 = 0X5A,

      /* Magnetometer Offset registers */

      MAG_OFFSET_X_LSB_ADDR                                   = 0X5B,

      MAG_OFFSET_X_MSB_ADDR                                   = 0X5C,

      MAG_OFFSET_Y_LSB_ADDR                                   = 0X5D,

      MAG_OFFSET_Y_MSB_ADDR                                   = 0X5E,

      MAG_OFFSET_Z_LSB_ADDR                                   = 0X5F,

      MAG_OFFSET_Z_MSB_ADDR                                   = 0X60,