uint8_t
MPU9250::read_reg(unsigned reg, uint32_t speed)
{
uint8_t buf;
if (_whoami == ICM_WHOAMI_20948) {
select_register_bank(REG_BANK(reg));
_interface->read(MPU9250_SET_SPEED(REG_ADDRESS(reg), speed), &buf, 1);
} else {
_interface->read(MPU9250_SET_SPEED(REG_ADDRESS(reg), speed), &buf, 1);
}
return buf;
}
uint8_t
MPU9250::read_reg(unsigned reg, uint32_t speed)
{
uint8_t buf;
_interface->read(MPU9250_SET_SPEED(reg, speed), &buf, 1);
return buf;
}
uint8_t
MPU9250::read_reg_range(unsigned start_reg, uint32_t speed, uint8_t *buf, uint16_t count)
{
uint8_t ret;
if (buf == NULL) { return PX4_ERROR; }
if (_whoami == ICM_WHOAMI_20948) {
select_register_bank(REG_BANK(start_reg));
ret = _interface->read(MPU9250_SET_SPEED(REG_ADDRESS(start_reg), speed), buf, count);
} else {
ret = _interface->read(MPU9250_SET_SPEED(REG_ADDRESS(start_reg), speed), buf, count);
}
return ret;
}
uint8_t
MPU9250::read_reg_range(unsigned start_reg, uint32_t speed, uint8_t *buf, uint16_t count)
{
if (buf == NULL) {
return PX4_ERROR;
}
return _interface->read(MPU9250_SET_SPEED(REG_ADDRESS(start_reg), speed), buf, count);
}
/*
deliberately trigger an error in the sensor to trigger recovery
*/
void
MPU9250::test_error()
{
// deliberately trigger an error. This was noticed during
// development as a handy way to test the reset logic
uint8_t data[16];
memset(data, 0, sizeof(data));
_interface->read(MPU9250_SET_SPEED(MPUREG_INT_STATUS, MPU9250_LOW_BUS_SPEED), data, sizeof(data));
::printf("error triggered\n");
print_registers();
}
void
MPU9250::measure()
{
if (hrt_absolute_time() < _reset_wait) {
// we're waiting for a reset to complete
return;
}
struct MPUReport mpu_report;
struct Report {
int16_t accel_x;
int16_t accel_y;
int16_t accel_z;
int16_t temp;
int16_t gyro_x;
int16_t gyro_y;
int16_t gyro_z;
} report;
/* start measuring */
perf_begin(_sample_perf);
/*
* Fetch the full set of measurements from the MPU9250 in one pass.
*/
if (OK != _interface->read(MPU9250_SET_SPEED(MPUREG_INT_STATUS, MPU9250_HIGH_BUS_SPEED),
(uint8_t *)&mpu_report,
sizeof(mpu_report))) {
return;
}
check_registers();
if (check_duplicate(&mpu_report.accel_x[0])) {
return;
}
#ifdef USE_I2C
if (_mag->is_passthrough()) {
#endif
_mag->_measure(mpu_report.mag);
#ifdef USE_I2C
} else {
_mag->measure();
}
#endif
/*
* Convert from big to little endian
*/
report.accel_x = int16_t_from_bytes(mpu_report.accel_x);
report.accel_y = int16_t_from_bytes(mpu_report.accel_y);
report.accel_z = int16_t_from_bytes(mpu_report.accel_z);
report.temp = int16_t_from_bytes(mpu_report.temp);
report.gyro_x = int16_t_from_bytes(mpu_report.gyro_x);
report.gyro_y = int16_t_from_bytes(mpu_report.gyro_y);
report.gyro_z = int16_t_from_bytes(mpu_report.gyro_z);
if (check_null_data((uint32_t *)&report, sizeof(report) / 4)) {
return;
}
if (_register_wait != 0) {
// we are waiting for some good transfers before using the sensor again
// We still increment _good_transfers, but don't return any data yet
_register_wait--;
return;
}
/*
* Swap axes and negate y
*/
int16_t accel_xt = report.accel_y;
int16_t accel_yt = ((report.accel_x == -32768) ? 32767 : -report.accel_x);
int16_t gyro_xt = report.gyro_y;
int16_t gyro_yt = ((report.gyro_x == -32768) ? 32767 : -report.gyro_x);
/*
* Apply the swap
*/
report.accel_x = accel_xt;
report.accel_y = accel_yt;
report.gyro_x = gyro_xt;
report.gyro_y = gyro_yt;
/*
* Report buffers.
*/
accel_report arb;
gyro_report grb;
/*
* Adjust and scale results to m/s^2.
*/
grb.timestamp = arb.timestamp = hrt_absolute_time();
// report the error count as the sum of the number of bad
// transfers and bad register reads. This allows the higher
// level code to decide if it should use this sensor based on
// whether it has had failures
grb.error_count = arb.error_count = perf_event_count(_bad_transfers) + perf_event_count(_bad_registers);
/*
* 1) Scale raw value to SI units using scaling from datasheet.
* 2) Subtract static offset (in SI units)
* 3) Scale the statically calibrated values with a linear
* dynamically obtained factor
*
* Note: the static sensor offset is the number the sensor outputs
* at a nominally 'zero' input. Therefore the offset has to
* be subtracted.
*
* Example: A gyro outputs a value of 74 at zero angular rate
* the offset is 74 from the origin and subtracting
* 74 from all measurements centers them around zero.
*/
/* NOTE: Axes have been swapped to match the board a few lines above. */
arb.x_raw = report.accel_x;
arb.y_raw = report.accel_y;
arb.z_raw = report.accel_z;
float xraw_f = report.accel_x;
float yraw_f = report.accel_y;
float zraw_f = report.accel_z;
// apply user specified rotation
rotate_3f(_rotation, xraw_f, yraw_f, zraw_f);
float x_in_new = ((xraw_f * _accel_range_scale) - _accel_scale.x_offset) * _accel_scale.x_scale;
float y_in_new = ((yraw_f * _accel_range_scale) - _accel_scale.y_offset) * _accel_scale.y_scale;
float z_in_new = ((zraw_f * _accel_range_scale) - _accel_scale.z_offset) * _accel_scale.z_scale;
arb.x = _accel_filter_x.apply(x_in_new);
arb.y = _accel_filter_y.apply(y_in_new);
arb.z = _accel_filter_z.apply(z_in_new);
math::Vector<3> aval(x_in_new, y_in_new, z_in_new);
math::Vector<3> aval_integrated;
bool accel_notify = _accel_int.put(arb.timestamp, aval, aval_integrated, arb.integral_dt);
arb.x_integral = aval_integrated(0);
arb.y_integral = aval_integrated(1);
arb.z_integral = aval_integrated(2);
arb.scaling = _accel_range_scale;
arb.range_m_s2 = _accel_range_m_s2;
_last_temperature = (report.temp) / 361.0f + 35.0f;
arb.temperature_raw = report.temp;
arb.temperature = _last_temperature;
grb.x_raw = report.gyro_x;
grb.y_raw = report.gyro_y;
grb.z_raw = report.gyro_z;
xraw_f = report.gyro_x;
yraw_f = report.gyro_y;
zraw_f = report.gyro_z;
// apply user specified rotation
rotate_3f(_rotation, xraw_f, yraw_f, zraw_f);
float x_gyro_in_new = ((xraw_f * _gyro_range_scale) - _gyro_scale.x_offset) * _gyro_scale.x_scale;
float y_gyro_in_new = ((yraw_f * _gyro_range_scale) - _gyro_scale.y_offset) * _gyro_scale.y_scale;
float z_gyro_in_new = ((zraw_f * _gyro_range_scale) - _gyro_scale.z_offset) * _gyro_scale.z_scale;
grb.x = _gyro_filter_x.apply(x_gyro_in_new);
grb.y = _gyro_filter_y.apply(y_gyro_in_new);
grb.z = _gyro_filter_z.apply(z_gyro_in_new);
math::Vector<3> gval(x_gyro_in_new, y_gyro_in_new, z_gyro_in_new);
math::Vector<3> gval_integrated;
bool gyro_notify = _gyro_int.put(arb.timestamp, gval, gval_integrated, grb.integral_dt);
grb.x_integral = gval_integrated(0);
grb.y_integral = gval_integrated(1);
grb.z_integral = gval_integrated(2);
grb.scaling = _gyro_range_scale;
grb.range_rad_s = _gyro_range_rad_s;
grb.temperature_raw = report.temp;
grb.temperature = _last_temperature;
_accel_reports->force(&arb);
_gyro_reports->force(&grb);
/* notify anyone waiting for data */
if (accel_notify) {
poll_notify(POLLIN);
}
if (gyro_notify) {
_gyro->parent_poll_notify();
}
if (accel_notify && !(_pub_blocked)) {
/* log the time of this report */
perf_begin(_controller_latency_perf);
/* publish it */
orb_publish(ORB_ID(sensor_accel), _accel_topic, &arb);
}
if (gyro_notify && !(_pub_blocked)) {
/* publish it */
orb_publish(ORB_ID(sensor_gyro), _gyro->_gyro_topic, &grb);
}
/* stop measuring */
perf_end(_sample_perf);
}
