This package contains the Bosch Sensortec's BMI160 sensor driver (sensor API)
The sensor driver package includes bmi160.h, bmi160.c and bmi160_defs.h files
| File | Version | Date |
|---|---|---|
| bmi160.c | 3.7.5 | 11 Jan 2018 |
| bmi160.h | 3.7.5 | 11 Jan 2018 |
| bmi160_defs.h | 3.7.5 | 11 Jan 2018 |
- Integrate bmi160.h, bmi160_defs.h and bmi160.c file in to your project.
- Include the bmi160.h file in your code like below.
#include "bmi160.h"- bmi160_defs.h : This header file has the constants, macros and datatype declarations.
- bmi160.h : This header file contains the declarations of the sensor driver APIs.
- bmi160.c : This source file contains the definitions of the sensor driver APIs.
- SPI 4-wire
- I2C
To initialize the sensor, you will first need to create a device structure. You can do this by creating an instance of the structure bmi160_dev. Then go on to fill in the various parameters as shown below.
struct bmi160_dev sensor;
/* You may assign a chip select identifier to be handled later */
sensor.id = 0;
sensor.interface = BMI160_SPI_INTF;
sensor.read = user_spi_read;
sensor.write = user_spi_write;
sensor.delay_ms = user_delay_ms;
int8_t rslt = BMI160_OK;
rslt = bmi160_init(&sensor);
/* After the above function call, accel_cfg and gyro_cfg parameters in the device
structure are set with default values, found in the datasheet of the sensor */struct bmi160_dev sensor;
sensor.id = BMI160_I2C_ADDR;
sensor.interface = BMI160_I2C_INTF;
sensor.read = user_i2c_read;
sensor.write = user_i2c_write;
sensor.delay_ms = user_delay_ms;
int8_t rslt = BMI160_OK;
rslt = bmi160_init(&sensor);
/* After the above function call, accel and gyro parameters in the device structure
are set with default values, found in the datasheet of the sensor */int8_t rslt = BMI160_OK;
/* Select the Output data rate, range of accelerometer sensor */
sensor.accel_cfg.odr = BMI160_ACCEL_ODR_1600HZ;
sensor.accel_cfg.range = BMI160_ACCEL_RANGE_2G;
sensor.accel_cfg.bw = BMI160_ACCEL_BW_NORMAL_AVG4;
/* Select the power mode of accelerometer sensor */
sensor.accel_cfg.power = BMI160_ACCEL_NORMAL_MODE;
/* Select the Output data rate, range of Gyroscope sensor */
sensor.gyro_cfg.odr = BMI160_GYRO_ODR_3200HZ;
sensor.gyro_cfg.range = BMI160_GYRO_RANGE_2000_DPS;
sensor.gyro_cfg.bw = BMI160_GYRO_BW_NORMAL_MODE;
/* Select the power mode of Gyroscope sensor */
sensor.gyro_cfg.power = BMI160_GYRO_NORMAL_MODE;
/* Set the sensor configuration */
rslt = bmi160_set_sens_conf(&sensor);int8_t rslt = BMI160_OK;
struct bmi160_sensor_data accel;
struct bmi160_sensor_data gyro;
/* To read only Accel data */
rslt = bmi160_get_sensor_data(BMI160_ACCEL_SEL, &accel, NULL, &sensor);
/* To read only Gyro data */
rslt = bmi160_get_sensor_data(BMI160_GYRO_SEL, NULL, &gyro, &sensor);
/* To read both Accel and Gyro data */
bmi160_get_sensor_data((BMI160_ACCEL_SEL | BMI160_GYRO_SEL), &accel, &gyro, &sensor);
/* To read Accel data along with time */
rslt = bmi160_get_sensor_data((BMI160_ACCEL_SEL | BMI160_TIME_SEL) , &accel, NULL, &sensor);
/* To read Gyro data along with time */
rslt = bmi160_get_sensor_data((BMI160_GYRO_SEL | BMI160_TIME_SEL), NULL, &gyro, &sensor);
/* To read both Accel and Gyro data along with time*/
bmi160_get_sensor_data((BMI160_ACCEL_SEL | BMI160_GYRO_SEL | BMI160_TIME_SEL), &accel, &gyro, &sensor);int8_t rslt = BMI160_OK;
/* Select the power mode */
sensor.accel_cfg.power = BMI160_ACCEL_SUSPEND_MODE;
sensor.gyro_cfg.power = BMI160_GYRO_FASTSTARTUP_MODE;
/* Set the Power mode */
rslt = bmi160_set_power_mode(&sensor);
/* Select the power mode */
sensor.accel_cfg.power = BMI160_ACCEL_NORMAL_MODE;
sensor.gyro_cfg.power = BMI160_GYRO_NORMAL_MODE;
/* Set the Power mode */
rslt = bmi160_set_power_mode(&sensor);int8_t rslt = BMI160_OK;
uint8_t reg_addr = BMI160_CHIP_ID_ADDR;
uint8_t data;
uint16_t len = 1;
rslt = bmi160_get_regs(reg_addr, &data, len, &sensor);int8_t rslt = BMI160_OK;
uint8_t reg_addr = BMI160_INT_MOTION_1_ADDR;
uint8_t data = 20;
uint16_t len = 1;
rslt = bmi160_set_regs(reg_addr, &data, len, &sensor);int8_t rslt = BMI160_OK;
rslt = bmi160_soft_reset(&sensor);To configure the sensor interrupts, you will first need to create an interrupt structure. You can do this by creating an instance of the structure bmi160_int_settg. Then go on to fill in the various parameters as shown below
Note:- User can check the currently active interrupt(any-motion or sig-motion) by checking the any_sig_sel of bmi160_dev structure.
struct bmi160_int_settg int_config;
/* Select the Interrupt channel/pin */
int_config.int_channel = BMI160_INT_CHANNEL_1;// Interrupt channel/pin 1
/* Select the Interrupt type */
int_config.int_type = BMI160_ACC_ANY_MOTION_INT;// Choosing Any motion interrupt
/* Select the interrupt channel/pin settings */
int_config.int_pin_settg.output_en = BMI160_ENABLE;// Enabling interrupt pins to act as output pin
int_config.int_pin_settg.output_mode = BMI160_DISABLE;// Choosing push-pull mode for interrupt pin
int_config.int_pin_settg.output_type = BMI160_DISABLE;// Choosing active low output
int_config.int_pin_settg.edge_ctrl = BMI160_ENABLE;// Choosing edge triggered output
int_config.int_pin_settg.input_en = BMI160_DISABLE;// Disabling interrupt pin to act as input
int_config.int_pin_settg.latch_dur = BMI160_LATCH_DUR_NONE;// non-latched output
/* Select the Any-motion interrupt parameters */
int_config.int_type_cfg.acc_any_motion_int.anymotion_en = BMI160_ENABLE;// 1- Enable the any-motion, 0- disable any-motion
int_config.int_type_cfg.acc_any_motion_int.anymotion_x = BMI160_ENABLE;// Enabling x-axis for any motion interrupt
int_config.int_type_cfg.acc_any_motion_int.anymotion_y = BMI160_ENABLE;// Enabling y-axis for any motion interrupt
int_config.int_type_cfg.acc_any_motion_int.anymotion_z = BMI160_ENABLE;// Enabling z-axis for any motion interrupt
int_config.int_type_cfg.acc_any_motion_int.anymotion_dur = 0;// any-motion duration
int_config.int_type_cfg.acc_any_motion_int.anymotion_thr = 20;// (2-g range) -> (slope_thr) * 3.91 mg, (4-g range) -> (slope_thr) * 7.81 mg, (8-g range) ->(slope_thr) * 15.63 mg, (16-g range) -> (slope_thr) * 31.25 mg
/* Set the Any-motion interrupt */
bmi160_set_int_config(&int_config, &sensor); /* sensor is an instance of the structure bmi160_dev */struct bmi160_int_settg int_config;
/* Select the Interrupt channel/pin */
int_config.int_channel = BMI160_INT_CHANNEL_1;// Interrupt channel/pin 1
/* Select the Interrupt type */
int_config.int_type = BMI160_ACC_FLAT_INT;// Choosing flat interrupt
/* Select the interrupt channel/pin settings */
int_config.int_pin_settg.output_en = BMI160_ENABLE;// Enabling interrupt pins to act as output pin
int_config.int_pin_settg.output_mode = BMI160_DISABLE;// Choosing push-pull mode for interrupt pin
int_config.int_pin_settg.output_type = BMI160_DISABLE;// Choosing active low output
int_config.int_pin_settg.edge_ctrl = BMI160_ENABLE;// Choosing edge triggered output
int_config.int_pin_settg.input_en = BMI160_DISABLE;// Disabling interrupt pin to act as input
int_config.int_pin_settg.latch_dur = BMI160_LATCH_DUR_NONE;// non-latched output
/* Select the Flat interrupt parameters */
int_config.int_type_cfg.acc_flat_int.flat_en = BMI160_ENABLE;// 1-enable, 0-disable the flat interrupt
int_config.int_type_cfg.acc_flat_int.flat_theta = 8;// threshold for detection of flat position in range from 0° to 44.8°.
int_config.int_type_cfg.acc_flat_int.flat_hy = 1;// Flat hysteresis
int_config.int_type_cfg.acc_flat_int.flat_hold_time = 1;// Flat hold time (0 -> 0 ms, 1 -> 640 ms, 2 -> 1280 ms, 3 -> 2560 ms)
/* Set the Flat interrupt */
bmi160_set_int_config(&int_config, &sensor); /* sensor is an instance of the structure bmi160_dev */struct bmi160_int_settg int_config;
/* Select the Interrupt channel/pin */
int_config.int_channel = BMI160_INT_CHANNEL_1;// Interrupt channel/pin 1
/* Select the Interrupt type */
int_config.int_type = BMI160_STEP_DETECT_INT;// Choosing Step Detector interrupt
/* Select the interrupt channel/pin settings */
int_config.int_pin_settg.output_en = BMI160_ENABLE;// Enabling interrupt pins to act as output pin
int_config.int_pin_settg.output_mode = BMI160_DISABLE;// Choosing push-pull mode for interrupt pin
int_config.int_pin_settg.output_type = BMI160_ENABLE;// Choosing active High output
int_config.int_pin_settg.edge_ctrl = BMI160_ENABLE;// Choosing edge triggered output
int_config.int_pin_settg.input_en = BMI160_DISABLE;// Disabling interrupt pin to act as input
int_config.int_pin_settg.latch_dur =BMI160_LATCH_DUR_NONE;// non-latched output
/* Select the Step Detector interrupt parameters, Kindly use the recommended settings for step detector */
int_config.int_type_cfg.acc_step_detect_int.step_detector_mode = BMI160_STEP_DETECT_NORMAL;
int_config.int_type_cfg.acc_step_detect_int.step_detector_en = BMI160_ENABLE;// 1-enable, 0-disable the step detector
/* Set the Step Detector interrupt */
bmi160_set_int_config(&int_config, &sensor); /* sensor is an instance of the structure bmi160_dev */To configure the step counter, user need to configure the step detector interrupt as described in above section. After configuring step detector, see the below code snippet for user space & ISR
int8_t rslt = BMI160_OK;
uint8_t step_enable = 1;//enable the step counter
rslt = bmi160_set_step_counter(step_enable, &sensor);int8_t rslt = BMI160_OK;
uint16_t step_count = 0;//stores the step counter value
rslt = bmi160_read_step_counter(&step_count, &sensor);struct bmi160_int_settg int_config;
/* Deselect the Interrupt channel/pin */
int_config.int_channel = BMI160_INT_CHANNEL_NONE;
/* Select the Interrupt type */
int_config.int_type = BMI160_STEP_DETECT_INT;// Choosing Step Detector interrupt
/* Set the Step Detector interrupt */
bmi160_set_int_config(&int_config, &sensor); /* sensor is an instance of the structure bmi160_dev */union bmi160_int_status interrupt;
enum bmi160_int_status_sel int_status_sel;
/* Interrupt status selection to read all interrupts */
int_status_sel = BMI160_INT_STATUS_ALL;
rslt = bmi160_get_int_status(int_status_sel, &interrupt, &sensor);
if (interrupt.bit.step)
printf("Step detector interrupt occured\n");It is assumed that secondary interface of bmi160 has external pull-up resistor in order to access the auxiliary sensor bmm150.
- Integrate the souce codes of BMM150 and BMI160 in project.
- Include the bmi160.h and bmm150.h file in your code like below.
- It is mandatory to initialize the bmi160 device structure for primary interface and auxiliary sensor settings.
- Create two wrapper functions , user_aux_read and user_aux_write in order to match the signature as mentioned below.
- Invoke the "bmi160_aux_init" API to initialise the secondary interface in BMI160.
- Invoke the "bmm150_init" API to initialise the BMM150 sensor.
- Now we can use the BMM150 sensor APIs to access the BMM150 via BMI160.
/* main.c file */
#include "bmi160.h"
#include "bmm150.h"
/* main.c file */
struct bmm150_dev bmm150;
/* function declaration */
int8_t user_aux_read(uint8_t id, uint8_t reg_addr, uint8_t *aux_data, uint16_t len);
int8_t user_aux_write(uint8_t id, uint8_t reg_addr, uint8_t *aux_data, uint16_t len);
/* Configure device structure for auxiliary sensor parameter */
sensor.aux_cfg.aux_sensor_enable = 1; // auxiliary sensor enable
sensor.aux_cfg.aux_i2c_addr = BMI160_AUX_BMM150_I2C_ADDR; // auxiliary sensor address
sensor.aux_cfg.manual_enable = 1; // setup mode enable
sensor.aux_cfg.aux_rd_burst_len = 2;// burst read of 2 byte
/* Configure the BMM150 device structure by
mapping user_aux_read and user_aux_write */
bmm150.read = user_aux_read;
bmm150.write = user_aux_write;
bmm150.id = BMM150_DEFAULT_I2C_ADDRESS;
/* Ensure that sensor.aux_cfg.aux_i2c_addr = bmm150.id
for proper sensor operation */
bmm150.delay_ms = delay_ms;
bmm150.interface = BMM150_I2C_INTF;
/* Initialize the auxiliary sensor interface */
rslt = bmi160_aux_init(&sensor);
/* Auxiliary sensor is enabled and can be accessed from this point */
/* Configure the desired settings in auxiliary BMM150 sensor
* using the bmm150 APIs */
/* Initialising the bmm150 sensor */
rslt = bmm150_init(&bmm150);
/* Set the power mode and preset mode to enable Mag data sampling */
bmm150.settings.pwr_mode = BMM150_NORMAL_MODE;
rslt = bmm150_set_op_mode(&bmm150);
bmm150.settings.preset_mode= BMM150_PRESETMODE_LOWPOWER;
rslt = bmm150_set_presetmode(&bmm150);
/*wrapper function to match the signature of bmm150.read */
int8_t user_aux_read(uint8_t id, uint8_t reg_addr, uint8_t *aux_data, uint16_t len)
{
int8_t rslt;
/* Discarding the parameter id as it is redundant*/
rslt = bmi160_aux_read(reg_addr, aux_data, len, &bmi160);
return rslt;
}
/*wrapper function to match the signature of bmm150.write */
int8_t user_aux_write(uint8_t id, uint8_t reg_addr, uint8_t *aux_data, uint16_t len)
{
int8_t rslt;
/* Discarding the parameter id as it is redundant */
rslt = bmi160_aux_write(reg_addr, aux_data, len, &bmi160);
return rslt;
}
Any sensor whose data bytes are less than or equal to 8 bytes can be synchronized with the BMI160 and read out of Accelerometer + Gyroscope + Auxiliary sensor data of that instance is possible which helps in creating less latency fusion data
/* Initialize the Auxiliary BMM150 following the above code
* until setting the power mode (Set the power mode as forced mode)
* and preset mode */
/* In BMM150 Mag data starts from register address 0x42 */
uint8_t aux_addr = 0x42;
/* Buffer to store the Mag data from 0x42 to 0x48 */
uint8_t mag_data[8] = {0};
uint8_t index;
/* Configure the Auxiliary sensor either in auto/manual modes and set the
polling frequency for the Auxiliary interface */
sensor.aux_cfg.aux_odr = 8; /* Represents polling rate in 100 Hz*/
rslt = bmi160_config_aux_mode(&sensor)
/* Set the auxiliary sensor to auto mode */
rslt = bmi160_set_aux_auto_mode(&aux_addr, &sensor);
/* Reading data from BMI160 data registers */
rslt = bmi160_read_aux_data_auto_mode(mag_data, &sensor);
printf("\n RAW DATA ");
for(index = 0 ; index < 8 ; index++)
{
printf("\n MAG DATA[%d] : %d ", index, mag_data[index]);
}
/* Compensating the raw mag data available from the BMM150 API */
rslt = bmm150_aux_mag_data(mag_data, &bmm150);
printf("\n COMPENSATED DATA ");
printf("\n MAG DATA X : %d Y : %d Z : %d", bmm150.data.x, bmm150.data.y, bmm150.data.z);
The Auxiliary sensor data can be stored in FIFO , Here we demonstrate an example for using the Bosch Magnetometer sensor BMM150 and storing its data in FIFO
/* Initialize the Aux BMM150 following the above
* code and by creating the Wrapper functions */
int8_t rslt = 0;
uint8_t aux_instance = 0;
uint16_t fifo_cnt = 0;
uint8_t auto_mode_addr;
uint8_t i;
/* Setup and configure the FIFO buffer */
/* Declare memory to store the raw FIFO buffer information */
uint8_t fifo_buff[1000] = {0};
/* Modify the FIFO buffer instance and link to the device instance */
struct bmi160_fifo_frame fifo_frame;
fifo_frame.data = fifo_buff;
fifo_frame.length = 1000;
dev->fifo = &fifo_frame;
/* Declare instances of the sensor data structure to store the parsed FIFO data */
struct bmi160_aux_data aux_data[112]; //1000 / 9 bytes per frame ~ 111 data frames
rslt = bmi160_init(dev);
printf("\n BMI160 chip ID is : %d ",dev->chip_id);
rslt = bmi160_aux_init(dev);
rslt = bmm150_init(&bmm150);
printf("\n BMM150 CHIP ID : %d",bmm150.chip_id);
bmm150.settings.preset_mode = BMM150_PRESETMODE_LOWPOWER;
rslt = bmm150_set_presetmode(&bmm150);
bmm150.settings.pwr_mode = BMM150_FORCED_MODE;
rslt = bmm150_set_op_mode(&bmm150);
/* Enter the data register of BMM150 to "auto_mode_addr" here it is 0x42 */
auto_mode_addr = 0x42;
printf("\n ENTERING AUX. AUTO MODE ");
dev->aux_cfg.aux_odr = BMI160_AUX_ODR_25HZ;
rslt = bmi160_set_aux_auto_mode(&auto_mode_addr, dev);
/* Disable other FIFO settings */
rslt = bmi160_set_fifo_config(BMI160_FIFO_CONFIG_1_MASK , BMI160_DISABLE, dev);
/* Enable the required FIFO settings */
rslt = bmi160_set_fifo_config(BMI160_FIFO_AUX | BMI160_FIFO_HEADER, BMI160_ENABLE, dev);
/* Delay for the FIFO to get filled */
dev->delay_ms(400);
printf("\n FIFO DATA REQUESTED (in bytes): %d",dev->fifo->length);
rslt = bmi160_get_fifo_data(dev);
printf("\n FIFO DATA AVAILABLE (in bytes): %d",dev->fifo->length);
/* Print the raw FIFO data obtained */
for(fifo_cnt = 0; fifo_cnt < dev->fifo->length ; fifo_cnt++) {
printf("\n FIFO DATA [%d] IS : %x ",fifo_cnt ,dev->fifo->data[fifo_cnt]);
}
printf("\n\n----------------------------------------------------\n");
/* Set the number of required sensor data instances */
aux_instance = 150;
/* Extract the aux data , 1frame = 8 data bytes */
printf("\n AUX DATA REQUESTED TO BE EXTRACTED (in frames): %d",aux_instance);
rslt = bmi160_extract_aux(aux_data, &aux_instance, dev);
printf("\n AUX DATA ACTUALLY EXTRACTED (in frames): %d",aux_instance);
/* Printing the raw aux data */
for (i = 0; i < aux_instance; i++) {
printf("\n Aux data[%d] : %x",i,aux_data[i].data[0]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[1]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[2]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[3]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[4]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[5]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[6]);
printf("\n Aux data[%d] : %x",i,aux_data[i].data[7]);
}
printf("\n\n----------------------------------------------------\n");
/* Compensate the raw mag data using BMM150 API */
for (i = 0; i < aux_instance; i++) {
printf("\n----------------------------------------------------");
printf("\n Aux data[%d] : %x , %x , %x , %x , %x , %x , %x , %x",i
,aux_data[i].data[0],aux_data[i].data[1]
,aux_data[i].data[2],aux_data[i].data[3]
,aux_data[i].data[4],aux_data[i].data[5]
,aux_data[i].data[6],aux_data[i].data[7]);
/* Compensated mag data using BMM150 API */
rslt = bmm150_aux_mag_data(&aux_data[i].data[0], &bmm150);
/* Printing the Compensated mag data */
if (rslt == BMM150_OK) {
printf("\n MAG DATA COMPENSATION USING BMM150 APIs");
printf("\n COMPENSATED DATA ");
printf("\n MAG DATA X : %d Y : %d Z : %d"
, bmm150.data.x, bmm150.data.y, bmm150.data.z);
} else {
printf("\n MAG DATA COMPENSATION IN BMM150 API is FAILED ");
}
printf("\n----------------------------------------------------\n");
}
/* Call the "bmi160_init" API as a prerequisite before performing self test
* since invoking self-test will reset the sensor */
rslt = bmi160_perform_self_test(BMI160_ACCEL_ONLY, sen);
/* Utilize the enum BMI160_GYRO_ONLY instead of BMI160_ACCEL_ONLY
to perform self test for gyro */
if (rslt == BMI160_OK) {
printf("\n ACCEL SELF TEST RESULT SUCCESS);
} else {
printf("\n ACCEL SELF TEST RESULT FAIL);
}
/* An example to read the Gyro data in header mode along with sensor time (if available)
* Configure the gyro sensor as prerequisite and follow the below example to read and
* obtain the gyro data from FIFO */
int8_t fifo_gyro_header_time_data(struct bmi160_dev *dev)
{
int8_t rslt = 0;
/* Declare memory to store the raw FIFO buffer information */
uint8_t fifo_buff[300];
/* Modify the FIFO buffer instance and link to the device instance */
struct bmi160_fifo_frame fifo_frame;
fifo_frame.data = fifo_buff;
fifo_frame.length = 300;
dev->fifo = &fifo_frame;
uint16_t index = 0;
/* Declare instances of the sensor data structure to store the parsed FIFO data */
struct bmi160_sensor_data gyro_data[42]; // 300 bytes / ~7bytes per frame ~ 42 data frames
uint8_t gyro_frames_req = 42;
uint8_t gyro_index;
/* Configure the sensor's FIFO settings */
rslt = bmi160_set_fifo_config(BMI160_FIFO_GYRO | BMI160_FIFO_HEADER | BMI160_FIFO_TIME,
BMI160_ENABLE, dev);
if (rslt == BMI160_OK) {
/* At ODR of 100 Hz ,1 frame gets updated in 1/100 = 0.01s
i.e. for 42 frames we need 42 * 0.01 = 0.42s = 420ms delay */
dev->delay_ms(420);
/* Read data from the sensor's FIFO and store it the FIFO buffer,"fifo_buff" */
printf("\n USER REQUESTED FIFO LENGTH : %d\n",dev->fifo->length);
rslt = bmi160_get_fifo_data(dev);
if (rslt == BMI160_OK) {
printf("\n AVAILABLE FIFO LENGTH : %d\n",dev->fifo->length);
/* Print the raw FIFO data */
for (index = 0; index < dev->fifo->length; index++) {
printf("\n FIFO DATA INDEX[%d] = %d", index,
dev->fifo->data[index]);
}
/* Parse the FIFO data to extract gyro data from the FIFO buffer */
printf("\n REQUESTED GYRO DATA FRAMES : %d\n ",gyro_frames_req);
rslt = bmi160_extract_gyro(gyro_data, &gyro_frames_req, dev);
if (rslt == BMI160_OK) {
printf("\n AVAILABLE GYRO DATA FRAMES : %d\n ",gyro_frames_req);
/* Print the parsed gyro data from the FIFO buffer */
for (gyro_index = 0; gyro_index < gyro_frames_req; gyro_index++) {
printf("\nFIFO GYRO FRAME[%d]",gyro_index);
printf("\nGYRO X-DATA : %d \t Y-DATA : %d \t Z-DATA : %d"
,gyro_data[gyro_index].x ,gyro_data[gyro_index].y
,gyro_data[gyro_index].z);
}
/* Print the special FIFO frame data like sensortime */
printf("\n SENSOR TIME DATA : %d \n",dev->fifo->sensor_time);
printf("SKIPPED FRAME COUNT : %d",dev->fifo->skipped_frame_count);
} else {
printf("\n Gyro data extraction failed");
}
} else {
printf("\n Reading FIFO data failed");
}
} else {
printf("\n Setting FIFO configuration failed");
}
return rslt;
}
FOC shouldnot be used in Low-power mode
/* An example for configuring FOC for accel and gyro data */
int8_t start_foc(struct bmi160_dev *dev)
{
int8_t rslt = 0;
/* FOC configuration structure */
struct bmi160_foc_conf foc_conf;
/* Structure to store the offsets */
struct bmi160_offsets offsets;
/* Enable FOC for accel with target values of z = 1g ; x,y as 0g */
foc_conf.acc_off_en = BMI160_ENABLE;
foc_conf.foc_acc_x = BMI160_FOC_ACCEL_0G;
foc_conf.foc_acc_y = BMI160_FOC_ACCEL_0G;
foc_conf.foc_acc_z = BMI160_FOC_ACCEL_POSITIVE_G;
/* Enable FOC for gyro */
foc_conf.foc_gyr_en = BMI160_ENABLE;
foc_conf.gyro_off_en = BMI160_ENABLE;
rslt = bmi160_start_foc(&foc_conf, &offsets, sen);
if (rslt == BMI160_OK) {
printf("\n FOC DONE SUCCESSFULLY ");
printf("\n OFFSET VALUES AFTER FOC : ");
printf("\n OFFSET VALUES ACCEL X : %d ",offsets.off_acc_x);
printf("\n OFFSET VALUES ACCEL Y : %d ",offsets.off_acc_y);
printf("\n OFFSET VALUES ACCEL Z : %d ",offsets.off_acc_z);
printf("\n OFFSET VALUES GYRO X : %d ",offsets.off_gyro_x);
printf("\n OFFSET VALUES GYRO Y : %d ",offsets.off_gyro_y);
printf("\n OFFSET VALUES GYRO Z : %d ",offsets.off_gyro_z);
}
/* After start of FOC offsets will be updated automatically and
* the data will be very much close to the target values of measurement */
return rslt;
}
The offsets set by this method will be reset on soft-reset/POR
/* An example for updating manual offsets to sensor */
int8_t write_offsets(struct bmi160_dev *dev)
{
int8_t rslt = 0;
/* FOC configuration structure */
struct bmi160_foc_conf foc_conf;
/* Structure to store the offsets */
struct bmi160_offsets offsets;
/* Enable offset update for accel */
foc_conf.acc_off_en = BMI160_ENABLE;
/* Enable offset update for gyro */
foc_conf.gyro_off_en = BMI160_ENABLE;
/* offset values set by user */
offsets.off_acc_x = 0x10;
offsets.off_acc_y = 0x10;
offsets.off_acc_z = 0x10;
offsets.off_gyro_x = 0x10;
offsets.off_gyro_y = 0x10;
offsets.off_gyro_z = 0x10;
rslt = bmi160_set_offsets(&foc_conf, &offsets, sen);
/* After offset setting the data read from the
* sensor will have the corresponding offset */
return rslt;
}
The offsets set by this method will be present in NVM and will be restored on POR/soft-reset
/* An example for updating manual offsets to sensor */
int8_t write_offsets_nvm(struct bmi160_dev *dev)
{
int8_t rslt = 0;
/* FOC configuration structure */
struct bmi160_foc_conf foc_conf;
/* Structure to store the offsets */
struct bmi160_offsets offsets;
/* Enable offset update for accel */
foc_conf.acc_off_en = BMI160_ENABLE;
/* Enable offset update for gyro */
foc_conf.gyro_off_en = BMI160_ENABLE;
/* offset values set by user as per their reference
* Resolution of accel = 3.9mg/LSB
* Resolution of gyro = (0.061degrees/second)/LSB */
offsets.off_acc_x = 10;
offsets.off_acc_y = -15;
offsets.off_acc_z = 20;
offsets.off_gyro_x = 30;
offsets.off_gyro_y = -35;
offsets.off_gyro_z = -40;
rslt = bmi160_set_offsets(&foc_conf, &offsets, sen);
if (rslt == BMI160_OK) {
/* Update the NVM */
rslt = bmi160_update_nvm(dev);
}
/* After this procedure the offsets are written to
* NVM and restored on POR/soft-reset
* The set values can be removed to ideal case by
* invoking the following APIs
* - bmi160_start_foc()
* - bmi160_update_nvm()
*/
return rslt;
}