Dan Perrett
Fork of Alexander Lill's BNO055_fusion library
BNO055.cpp
- Committer:
- AlexanderLill
- Date:
- 2018-01-28
- Revision:
- 11:17bc36c5ccbb
- Parent:
- 10:63a9849f0e97
- Child:
- 13:92854c8deb3c
File content as of revision 11:17bc36c5ccbb:
/*
* mbed library program
* BNO055 Intelligent 9-axis absolute orientation sensor
* by Bosch Sensortec
*
* Copyright (c) 2015,'17 Kenji Arai / JH1PJL
* http://www.page.sannet.ne.jp/kenjia/index.html
* http://mbed.org/users/kenjiArai/
* Created: March 30th, 2015
* Revised: August 23rd, 2017
*/
#include "mbed.h"
#include "BNO055.h"
#if MBED_MAJOR_VERSION == 2
#define WAIT_MS(x) wait_ms(x)
#elif MBED_MAJOR_VERSION == 5
#define WAIT_MS(x) Thread::wait(x)
#else
#error "Running on Unknown OS"
#endif
BNO055::BNO055 (PinName p_sda, PinName p_scl, PinName p_reset, uint8_t addr, uint8_t mode):
_i2c_p(new I2C(p_sda, p_scl)), _i2c(*_i2c_p), _res(p_reset)
{
chip_addr = addr;
chip_mode = mode;
initialize ();
}
BNO055::BNO055 (PinName p_sda, PinName p_scl, PinName p_reset) :
_i2c_p(new I2C(p_sda, p_scl)), _i2c(*_i2c_p), _res(p_reset)
{
chip_addr = BNO055_G_CHIP_ADDR;
chip_mode = MODE_NDOF;
initialize ();
}
BNO055::BNO055 (I2C& p_i2c, PinName p_reset, uint8_t addr, uint8_t mode) :
_i2c(p_i2c), _res(p_reset)
{
chip_addr = addr;
chip_mode = mode;
initialize ();
}
BNO055::BNO055 (I2C& p_i2c, PinName p_reset) :
_i2c(p_i2c), _res(p_reset)
{
chip_addr = BNO055_G_CHIP_ADDR;
chip_mode = MODE_NDOF;
initialize ();
}
/////////////// Read data & normalize /////////////////////
void BNO055::get_euler_angles(BNO055_EULER_TypeDef *result)
{
int16_t h,p,r;
select_page(0);
dt[0] = BNO055_EULER_H_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 6, false);
h = dt[1] << 8 | dt[0];
p = dt[3] << 8 | dt[2];
r = dt[5] << 8 | dt[4];
if (use_degrees()) {
result->h = (double)h / 16;
result->p = (double)p / 16;
result->r = (double)r / 16;
} else {
result->h = (double)h / 900;
result->p = (double)p / 900;
result->r = (double)r / 900;
}
}
void BNO055::get_quaternion(BNO055_QUATERNION_TypeDef *result)
{
int16_t w,x,y,z;
select_page(0);
dt[0] = BNO055_QUATERNION_W_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 8, false);
w = (dt[1] << 8 | dt[0]);
x = (dt[3] << 8 | dt[2]);
y = (dt[5] << 8 | dt[4]);
z = (dt[7] << 8 | dt[6]);
result->w = double(w) / 16384.0f;
result->x = double(x) / 16384.0f;
result->y = double(y) / 16384.0f;
result->z = double(z) / 16384.0f;
}
void BNO055::get_linear_accel(BNO055_VECTOR_TypeDef *result)
{
int16_t x,y,z;
select_page(0);
dt[0] = BNO055_LINEAR_ACC_X_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 6, false);
x = dt[1] << 8 | dt[0];
y = dt[3] << 8 | dt[2];
z = dt[5] << 8 | dt[4];
if (use_mss()) {
result->x = (double)x / 100;
result->y = (double)y / 100;
result->z = (double)z / 100;
} else {
result->x = (double)x;
result->y = (double)y;
result->z = (double)z;
}
}
void BNO055::get_gravity(BNO055_VECTOR_TypeDef *result)
{
int16_t x,y,z;
select_page(0);
dt[0] = BNO055_GRAVITY_X_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 6, false);
x = dt[1] << 8 | dt[0];
y = dt[3] << 8 | dt[2];
z = dt[5] << 8 | dt[4];
if (use_mss()) {
result->x = (double)x / 100;
result->y = (double)y / 100;
result->z = (double)z / 100;
} else {
result->x = (double)x;
result->y = (double)y;
result->z = (double)z;
}
}
void BNO055::get_mag(BNO055_VECTOR_TypeDef *result)
{
int16_t x,y,z;
select_page(0);
dt[0] = BNO055_MAG_X_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 6, false);
x = dt[1] << 8 | dt[0];
y = dt[3] << 8 | dt[2];
z = dt[5] << 8 | dt[4];
result->x = (double)x;
result->y = (double)y;
result->z = (double)z;
}
void BNO055::get_accel(BNO055_VECTOR_TypeDef *result)
{
int16_t x,y,z;
select_page(0);
dt[0] = BNO055_ACC_X_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 6, false);
x = dt[1] << 8 | dt[0];
y = dt[3] << 8 | dt[2];
z = dt[5] << 8 | dt[4];
if (use_mss()) {
result->x = (double)x / 100;
result->y = (double)y / 100;
result->z = (double)z / 100;
} else {
result->x = (double)x;
result->y = (double)y;
result->z = (double)z;
}
}
void BNO055::get_gyro(BNO055_VECTOR_TypeDef *result)
{
int16_t x,y,z;
select_page(0);
dt[0] = BNO055_GYR_X_LSB;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 6, false);
x = dt[1] << 8 | dt[0];
y = dt[3] << 8 | dt[2];
z = dt[5] << 8 | dt[4];
if (use_dps()) {
result->x = (double)x / 16;
result->y = (double)y / 16;
result->z = (double)z / 16;
} else {
result->x = (double)x / 900;
result->y = (double)y / 900;
result->z = (double)z / 900;
}
}
void BNO055::get_chip_temperature(BNO055_TEMPERATURE_TypeDef *result)
{
select_page(0);
uint8_t use_celsius_result = use_celsius();
dt[0] = BNO055_TEMP_SOURCE;
dt[1] = 0;
_i2c.write(chip_addr, dt, 2, false);
WAIT_MS(1); // Do I need to wait?
dt[0] = BNO055_TEMP;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
if (use_celsius_result) {
result->acc_chip = (int8_t)dt[0];
} else {
result->acc_chip = (int8_t)dt[0] * 2;
}
dt[0] = BNO055_TEMP_SOURCE;
dt[1] = 1;
_i2c.write(chip_addr, dt, 2, false);
WAIT_MS(1); // Do I need to wait?
dt[0] = BNO055_TEMP;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
if (use_celsius_result) {
result->gyr_chip = (int8_t)dt[0];
} else {
result->gyr_chip = (int8_t)dt[0] * 2;
}
}
/////////////// Initialize ////////////////////////////////
void BNO055::initialize (void)
{
#if defined(TARGET_STM32L152RE)
_i2c.frequency(100000);
#else
_i2c.frequency(400000);
#endif
page_flag = 0xff;
select_page(0);
// Check Acc & Mag & Gyro are available of not
get_id();
// Set initial data
set_initial_dt_to_regs();
// Unit selection
unit_selection();
// Set fusion mode
change_fusion_mode(chip_mode);
}
void BNO055::unit_selection(void)
{
select_page(0);
dt[0] = BNO055_UNIT_SEL;
dt[1] = UNIT_ORI_WIN + UNIT_ACC_MSS + UNIT_GYR_DPS + UNIT_EULER_DEG + UNIT_TEMP_C;
_i2c.write(chip_addr, dt, 2, false);
}
bool BNO055::use_degrees()
{
if (unit_flag_is_set(UNIT_EULER_RAD)) {
return false;
}
return true;
}
bool BNO055::use_mss()
{
if (unit_flag_is_set(UNIT_ACC_MG)) {
return false;
}
return true;
}
bool BNO055::use_dps()
{
if (unit_flag_is_set(UNIT_GYR_RPS)) {
return false;
}
return true;
}
bool BNO055::use_celsius()
{
if (unit_flag_is_set(UNIT_TEMP_F)) {
return false;
}
return true;
}
bool BNO055::unit_flag_is_set(uint8_t flag)
{
select_page(0);
dt[0] = BNO055_UNIT_SEL;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
if (dt[0] & flag) {
return true;
}
return false;
}
uint8_t BNO055::select_page(uint8_t page)
{
if (page != page_flag){
dt[0] = BNO055_PAGE_ID;
if (page == 1) {
dt[1] = 1; // select page 1
} else {
dt[1] = 0; // select page 0
}
_i2c.write(chip_addr, dt, 2, false);
dt[0] = BNO055_PAGE_ID;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
page_flag = dt[0];
}
return page_flag;
}
uint8_t BNO055::reset(void)
{
_res = 0;
WAIT_MS(1); // Reset 1mS
_res = 1;
WAIT_MS(700); // Need to wait at least 650mS
#if defined(TARGET_STM32L152RE)
_i2c.frequency(400000);
#else
_i2c.frequency(400000);
#endif
_i2c.stop();
page_flag = 0xff;
select_page(0);
get_id();
if (chip_id != I_AM_BNO055_CHIP){
return 1;
} else {
initialize();
return 0;
}
}
////// Set initialize data to related registers ///////////
void BNO055::set_initial_dt_to_regs(void)
{
// select_page(0);
// current setting is only used default values
}
/////////////// Check Who am I? ///////////////////////////
void BNO055::get_id(void)
{
select_page(0);
// ID
dt[0] = BNO055_CHIP_ID;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 7, false);
chip_id = dt[0];
if (chip_id == I_AM_BNO055_CHIP) {
ready_flag = 1;
} else {
ready_flag = 0;
}
acc_id = dt[1];
if (acc_id == I_AM_BNO055_ACC) {
ready_flag |= 2;
}
mag_id = dt[2];
if (mag_id == I_AM_BNO055_MAG) {
ready_flag |= 4;
}
gyr_id = dt[3];
if (mag_id == I_AM_BNO055_MAG) {
ready_flag |= 8;
}
bootldr_rev_id = dt[5]<< 8 | dt[4];
sw_rev_id = dt[6];
}
void BNO055::read_id_inf(BNO055_ID_INF_TypeDef *id)
{
id->chip_id = chip_id;
id->acc_id = acc_id;
id->mag_id = mag_id;
id->gyr_id = gyr_id;
id->bootldr_rev_id = bootldr_rev_id;
id->sw_rev_id = sw_rev_id;
}
/////////////// Check chip ready or not //////////////////
uint8_t BNO055::chip_ready(void)
{
if (ready_flag == 0x0f) {
return 1;
}
return 0;
}
/////////////// Read Calibration status //////////////////
uint8_t BNO055::read_calib_status(void)
{
select_page(0);
dt[0] = BNO055_CALIB_STAT;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
return dt[0];
}
/////////////// Change Fusion mode ///////////////////////
void BNO055::change_fusion_mode(uint8_t mode)
{
uint8_t current_mode;
select_page(0);
current_mode = get_operating_mode();
switch (mode) {
case CONFIGMODE:
dt[0] = BNO055_OPR_MODE;
dt[1] = mode;
_i2c.write(chip_addr, dt, 2, false);
WAIT_MS(19); // wait 19mS
break;
case MODE_IMU:
case MODE_COMPASS:
case MODE_M4G:
case MODE_NDOF_FMC_OFF:
case MODE_NDOF:
if (current_mode != CONFIGMODE) { // Can we change the mode directry?
dt[0] = BNO055_OPR_MODE;
dt[1] = CONFIGMODE;
_i2c.write(chip_addr, dt, 2, false);
WAIT_MS(19); // wait 19mS
}
dt[0] = BNO055_OPR_MODE;
dt[1] = mode;
_i2c.write(chip_addr, dt, 2, false);
WAIT_MS(7); // wait 7mS
break;
default:
break;
}
}
uint8_t BNO055::get_operating_mode(void)
{
select_page(0);
dt[0] = BNO055_OPR_MODE;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
return dt[0];
}
/////////////// Set Mouting position /////////////////////
void BNO055::set_mounting_position(uint8_t position)
{
uint8_t remap_config;
uint8_t remap_sign;
uint8_t current_mode;
current_mode = get_operating_mode();
change_fusion_mode(CONFIGMODE);
switch (position) {
case MT_P0:
remap_config = 0x21;
remap_sign = 0x04;
break;
case MT_P2:
remap_config = 0x24;
remap_sign = 0x06;
break;
case MT_P3:
remap_config = 0x21;
remap_sign = 0x02;
break;
case MT_P4:
remap_config = 0x24;
remap_sign = 0x03;
break;
case MT_P5:
remap_config = 0x21;
remap_sign = 0x01;
break;
case MT_P6:
remap_config = 0x21;
remap_sign = 0x07;
break;
case MT_P7:
remap_config = 0x24;
remap_sign = 0x05;
break;
case MT_P1:
default:
remap_config = 0x24;
remap_sign = 0x00;
break;
}
dt[0] = BNO055_AXIS_MAP_CONFIG;
dt[1] = remap_config;
dt[2] = remap_sign;
_i2c.write(chip_addr, dt, 3, false);
change_fusion_mode(current_mode);
}
/////////////// I2C Freq. /////////////////////////////////
void BNO055::frequency(int hz)
{
_i2c.frequency(hz);
}
/////////////// Read/Write specific register //////////////
uint8_t BNO055::read_reg0(uint8_t addr)
{
select_page(0);
dt[0] = addr;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
return (uint8_t)dt[0];
}
uint8_t BNO055::write_reg0(uint8_t addr, uint8_t data)
{
uint8_t current_mode;
uint8_t d;
current_mode = get_operating_mode();
change_fusion_mode(CONFIGMODE);
dt[0] = addr;
dt[1] = data;
_i2c.write(chip_addr, dt, 2, false);
d = dt[0];
change_fusion_mode(current_mode);
return d;
}
uint8_t BNO055::read_reg1(uint8_t addr)
{
select_page(1);
dt[0] = addr;
_i2c.write(chip_addr, dt, 1, true);
_i2c.read(chip_addr, dt, 1, false);
return (uint8_t)dt[0];
}
uint8_t BNO055::write_reg1(uint8_t addr, uint8_t data)
{
uint8_t current_mode;
uint8_t d;
current_mode = get_operating_mode();
change_fusion_mode(CONFIGMODE);
select_page(1);
dt[0] = addr;
dt[1] = data;
_i2c.write(chip_addr, dt, 2, false);
d = dt[0];
change_fusion_mode(current_mode);
return d;
}