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/*
This program is free software : you can redistribute it and / or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation , either version 3 of the License , or
( at your option ) any later version .
This program is distributed in the hope that it will be useful ,
but WITHOUT ANY WARRANTY ; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
GNU General Public License for more details .
You should have received a copy of the GNU General Public License
along with this program . If not , see < http : //www.gnu.org/licenses/>.
*/
/*
IMU temperature calibration handling
*/
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# define AP_INLINE_VECTOR_OPS
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# include "AP_InertialSensor_tempcal.h"
# include "AP_InertialSensor_config.h"
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# if HAL_INS_TEMPERATURE_CAL_ENABLE
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# include <GCS_MAVLink/GCS.h>
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# include <AP_Logger/AP_Logger.h>
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# include <AP_Common/ExpandingString.h>
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# include <AP_Notify/AP_Notify.h>
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// this scale factor ensures params are easy to work with in GUI parameter editors
# define SCALE_FACTOR 1.0e6
# define INV_SCALE_FACTOR 1.0e-6
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# define TEMP_RANGE_MIN 10
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// timeout calibration after 10 minutes, if no temperature rise
# define CAL_TIMEOUT_MS (600U*1000U)
/*
we use a fixed reference temperature of 35 C . This has the advantage
that we don ' t need to know the final temperature when doing an
online calibration which allows us to have a calibration timeout
*/
# define TEMP_REFERENCE 35.0
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extern const AP_HAL : : HAL & hal ;
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// temperature calibration parameters, per IMU
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const AP_Param : : GroupInfo AP_InertialSensor_TCal : : var_info [ ] = {
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// @Param: ENABLE
// @DisplayName: Enable temperature calibration
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// @Description: Enable the use of temperature calibration parameters for this IMU. For automatic learning set to 2 and also set the INS_TCALn_TMAX to the target temperature, then reboot
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// @Values: 0:Disabled,1:Enabled,2:LearnCalibration
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// @User: Advanced
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// @RebootRequired: True
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AP_GROUPINFO_FLAGS ( " ENABLE " , 1 , AP_InertialSensor_TCal , enable , float ( Enable : : Disabled ) , AP_PARAM_FLAG_ENABLE ) ,
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// @Param: TMIN
// @DisplayName: Temperature calibration min
// @Description: The minimum temperature that the calibration is valid for
// @Range: -70 80
// @Units: degC
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " TMIN " , 2 , AP_InertialSensor_TCal , temp_min , 0 ) ,
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// @Param: TMAX
// @DisplayName: Temperature calibration max
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// @Description: The maximum temperature that the calibration is valid for. This must be at least 10 degrees above TMIN for calibration
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// @Range: -70 80
// @Units: degC
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " TMAX " , 3 , AP_InertialSensor_TCal , temp_max , 70 ) ,
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// @Param: ACC1_X
// @DisplayName: Accelerometer 1st order temperature coefficient X axis
// @Description: This is the 1st order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: ACC1_Y
// @DisplayName: Accelerometer 1st order temperature coefficient Y axis
// @Description: This is the 1st order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: ACC1_Z
// @DisplayName: Accelerometer 1st order temperature coefficient Z axis
// @Description: This is the 1st order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " ACC1 " , 4 , AP_InertialSensor_TCal , accel_coeff [ 0 ] , 0 ) ,
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// @Param: ACC2_X
// @DisplayName: Accelerometer 2nd order temperature coefficient X axis
// @Description: This is the 2nd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: ACC2_Y
// @DisplayName: Accelerometer 2nd order temperature coefficient Y axis
// @Description: This is the 2nd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: ACC2_Z
// @DisplayName: Accelerometer 2nd order temperature coefficient Z axis
// @Description: This is the 2nd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " ACC2 " , 5 , AP_InertialSensor_TCal , accel_coeff [ 1 ] , 0 ) ,
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// @Param: ACC3_X
// @DisplayName: Accelerometer 3rd order temperature coefficient X axis
// @Description: This is the 3rd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: ACC3_Y
// @DisplayName: Accelerometer 3rd order temperature coefficient Y axis
// @Description: This is the 3rd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: ACC3_Z
// @DisplayName: Accelerometer 3rd order temperature coefficient Z axis
// @Description: This is the 3rd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " ACC3 " , 6 , AP_InertialSensor_TCal , accel_coeff [ 2 ] , 0 ) ,
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// @Param: GYR1_X
// @DisplayName: Gyroscope 1st order temperature coefficient X axis
// @Description: This is the 1st order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: GYR1_Y
// @DisplayName: Gyroscope 1st order temperature coefficient Y axis
// @Description: This is the 1st order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: GYR1_Z
// @DisplayName: Gyroscope 1st order temperature coefficient Z axis
// @Description: This is the 1st order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " GYR1 " , 7 , AP_InertialSensor_TCal , gyro_coeff [ 0 ] , 0 ) ,
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// @Param: GYR2_X
// @DisplayName: Gyroscope 2nd order temperature coefficient X axis
// @Description: This is the 2nd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: GYR2_Y
// @DisplayName: Gyroscope 2nd order temperature coefficient Y axis
// @Description: This is the 2nd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: GYR2_Z
// @DisplayName: Gyroscope 2nd order temperature coefficient Z axis
// @Description: This is the 2nd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " GYR2 " , 8 , AP_InertialSensor_TCal , gyro_coeff [ 1 ] , 0 ) ,
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// @Param: GYR3_X
// @DisplayName: Gyroscope 3rd order temperature coefficient X axis
// @Description: This is the 3rd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: GYR3_Y
// @DisplayName: Gyroscope 3rd order temperature coefficient Y axis
// @Description: This is the 3rd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
// @Param: GYR3_Z
// @DisplayName: Gyroscope 3rd order temperature coefficient Z axis
// @Description: This is the 3rd order temperature coefficient from a temperature calibration
// @User: Advanced
// @Calibration: 1
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AP_GROUPINFO ( " GYR3 " , 9 , AP_InertialSensor_TCal , gyro_coeff [ 2 ] , 0 ) ,
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AP_GROUPEND
} ;
/*
evaluate a 3 rd order polynomial ( without the constant term ) given a set of coefficients
*/
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Vector3f AP_InertialSensor_TCal : : polynomial_eval ( float tdiff , const AP_Vector3f coeff [ 3 ] ) const
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{
// evaluate order 3 polynomial
const Vector3f * c = ( Vector3f * ) & coeff [ 0 ] ;
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return ( c [ 0 ] + ( c [ 1 ] + c [ 2 ] * tdiff ) * tdiff ) * tdiff * INV_SCALE_FACTOR ;
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}
/*
correct a single sensor for the current temperature
*/
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void AP_InertialSensor_TCal : : correct_sensor ( float temperature , float cal_temp , const AP_Vector3f coeff [ 3 ] , Vector3f & v ) const
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{
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if ( enable ! = Enable : : Enabled ) {
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return ;
}
temperature = constrain_float ( temperature , temp_min , temp_max ) ;
cal_temp = constrain_float ( cal_temp , temp_min , temp_max ) ;
// get the polynomial correction for the difference between the
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// current temperature and the mid temperature
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v - = polynomial_eval ( temperature - TEMP_REFERENCE , coeff ) ;
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// we need to add the correction for the temperature
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// difference between the TREF, which is the reference used for
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// the calibration process, and the cal_temp, which is the
// temperature that the offsets and scale factors was setup for
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v + = polynomial_eval ( cal_temp - TEMP_REFERENCE , coeff ) ;
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}
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void AP_InertialSensor_TCal : : correct_accel ( float temperature , float cal_temp , Vector3f & accel ) const
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{
correct_sensor ( temperature , cal_temp , accel_coeff , accel ) ;
}
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void AP_InertialSensor_TCal : : correct_gyro ( float temperature , float cal_temp , Vector3f & gyro ) const
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{
correct_sensor ( temperature , cal_temp , gyro_coeff , gyro ) ;
}
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/*
for SITL we don ' t apply the temperature limits and use mid - point as
reference . This makes the SITL data independent of TEMP_REFERENCE
and prevents an abrupt change at the endpoints
*/
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void AP_InertialSensor_TCal : : sitl_apply_accel ( float temperature , Vector3f & accel ) const
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{
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const float tmid = 0.5 * ( temp_max + temp_min ) ;
accel + = polynomial_eval ( temperature - tmid , accel_coeff ) ;
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}
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void AP_InertialSensor_TCal : : sitl_apply_gyro ( float temperature , Vector3f & gyro ) const
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{
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const float tmid = 0.5 * ( temp_max + temp_min ) ;
gyro + = polynomial_eval ( temperature - tmid , gyro_coeff ) ;
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}
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AP_InertialSensor_TCal : : Learn : : Learn ( AP_InertialSensor_TCal & _tcal , float _start_temp ) :
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start_temp ( _start_temp ) ,
tcal ( _tcal )
{
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reset ( _start_temp ) ;
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}
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/*
update polyfit with new sample
*/
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void AP_InertialSensor_TCal : : Learn : : add_sample ( const Vector3f & sample , float temperature , struct LearnState & st )
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{
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temperature = st . temp_filter . apply ( temperature ) ;
st . sum + = sample ;
st . sum_count + + ;
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uint32_t now = AP_HAL : : millis ( ) ;
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if ( st . sum_count < 100 | |
temperature - st . last_temp < 0.5 ) {
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// check for timeout
if ( st . last_sample_ms ! = 0 & &
temperature - start_temp > = TEMP_RANGE_MIN & &
now - st . last_sample_ms > CAL_TIMEOUT_MS ) {
// we have timed out, finish up now
finish_calibration ( st . last_temp ) ;
}
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// wait for more data
return ;
}
st . sum / = st . sum_count ;
const uint8_t si = & st - & state [ 0 ] ;
const float T = ( temperature + st . last_temp ) * 0.5 ;
if ( si = = 0 ) {
// we use the first accel sample as the zero baseline
if ( accel_start . is_zero ( ) ) {
accel_start = st . sum ;
start_temp = T ;
}
st . sum - = accel_start ;
}
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const float tdiff = T - TEMP_REFERENCE ;
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# if HAL_LOGGING_ENABLED
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AP : : logger ( ) . Write ( " TCLR " , " TimeUS,I,SType,Temp,X,Y,Z,NSamp " ,
" s#------ " ,
" F000000- " ,
" QBBffffI " ,
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AP_HAL : : micros64 ( ) ,
instance ( ) ,
si ,
T ,
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st . sum . x , st . sum . y , st . sum . z ,
st . sum_count ) ;
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# endif
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st . pfit . update ( tdiff , st . sum ) ;
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st . sum . zero ( ) ;
st . sum_count = 0 ;
st . last_temp = temperature ;
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st . last_sample_ms = now ;
if ( temperature - start_temp > = TEMP_RANGE_MIN ) {
if ( temperature > = start_tmax ) {
// we've reached the target temperature
finish_calibration ( temperature ) ;
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} else if ( now - last_save_ms > 15000 ) {
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// save partial calibration, so if user stops the cal part
// way then they still have a useful calibration
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last_save_ms = now ;
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save_calibration ( st . last_temp ) ;
}
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}
}
/*
update accel temperature compensation learning
*/
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void AP_InertialSensor_TCal : : update_accel_learning ( const Vector3f & accel , float temperature )
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{
if ( enable ! = Enable : : LearnCalibration ) {
return ;
}
if ( learn = = nullptr & & hal . scheduler - > is_system_initialized ( ) ) {
learn = new Learn ( * this , temperature ) ;
if ( learn ) {
GCS_SEND_TEXT ( MAV_SEVERITY_WARNING , " TCAL[%u]: started calibration t=%.1fC tmax=%.1fC " ,
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instance ( ) + 1 ,
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temperature , learn - > start_tmax ) ;
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AP_Notify : : events . initiated_temp_cal = 1 ;
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}
}
if ( learn ! = nullptr ) {
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AP_Notify : : flags . temp_cal_running = true ;
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learn - > add_sample ( accel , temperature , learn - > state [ 0 ] ) ;
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}
}
/*
update gyro temperature compensation learning
*/
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void AP_InertialSensor_TCal : : update_gyro_learning ( const Vector3f & gyro , float temperature )
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{
if ( enable ! = Enable : : LearnCalibration ) {
return ;
}
if ( learn ! = nullptr ) {
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learn - > add_sample ( gyro , temperature , learn - > state [ 1 ] ) ;
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}
}
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/*
reset calibration
*/
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void AP_InertialSensor_TCal : : Learn : : reset ( float temperature )
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{
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memset ( ( void * ) & state [ 0 ] , 0 , sizeof ( state ) ) ;
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start_tmax = tcal . temp_max ;
accel_start . zero ( ) ;
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for ( uint8_t i = 0 ; i < ARRAY_SIZE ( state ) ; i + + ) {
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state [ i ] . temp_filter . set_cutoff_frequency ( 1000 , 0.5 ) ;
state [ i ] . temp_filter . reset ( temperature ) ;
state [ i ] . last_temp = temperature ;
}
}
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/*
finish and save calibration
*/
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void AP_InertialSensor_TCal : : Learn : : finish_calibration ( float temperature )
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{
if ( ! save_calibration ( temperature ) ) {
GCS_SEND_TEXT ( MAV_SEVERITY_WARNING , " TCAL[%u]: failed fit " , instance ( ) + 1 ) ;
AP_Notify : : events . temp_cal_failed = 1 ;
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tcal . enable . set_and_save_ifchanged ( int8_t ( AP_InertialSensor_TCal : : Enable : : Disabled ) ) ;
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return ;
}
GCS_SEND_TEXT ( MAV_SEVERITY_WARNING , " TCAL[%u]: completed calibration tmin=%.1f tmax=%.1f " ,
instance ( ) + 1 ,
tcal . temp_min . get ( ) , tcal . temp_max . get ( ) ) ;
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tcal . enable . set_and_save_ifchanged ( int8_t ( AP_InertialSensor_TCal : : Enable : : Enabled ) ) ;
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}
/*
save calibration state
*/
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bool AP_InertialSensor_TCal : : Learn : : save_calibration ( float temperature )
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{
Vector3f coefficients [ 3 ] ;
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Vector3f p [ 4 ] ;
if ( ! state [ 0 ] . pfit . get_polynomial ( p ) ) {
return false ;
}
for ( uint8_t k = 0 ; k < 3 ; k + + ) {
coefficients [ k ] = p [ 2 - k ] * SCALE_FACTOR ;
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}
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for ( uint8_t k = 0 ; k < 3 ; k + + ) {
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tcal . accel_coeff [ k ] . set_and_save_ifchanged ( coefficients [ k ] ) ;
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}
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if ( ! state [ 1 ] . pfit . get_polynomial ( p ) ) {
return false ;
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}
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for ( uint8_t k = 0 ; k < 3 ; k + + ) {
coefficients [ k ] = p [ 2 - k ] * SCALE_FACTOR ;
}
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for ( uint8_t k = 0 ; k < 3 ; k + + ) {
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tcal . gyro_coeff [ k ] . set_and_save_ifchanged ( coefficients [ k ] ) ;
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}
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tcal . temp_min . set_and_save_ifchanged ( start_temp ) ;
tcal . temp_max . set_and_save_ifchanged ( temperature ) ;
return true ;
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}
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uint8_t AP_InertialSensor_TCal : : instance ( void ) const
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{
return AP : : ins ( ) . tcal_instance ( * this ) ;
}
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/*
get a string representation of parameters for this calibration set
*/
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void AP_InertialSensor_TCal : : get_persistent_params ( ExpandingString & str ) const
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{
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if ( enable ! = AP_InertialSensor_TCal : : Enable : : Enabled ) {
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return ;
}
const uint8_t imu = instance ( ) + 1 ;
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# if INS_AUX_INSTANCES
if ( imu > 3 ) {
str . printf ( " INS%u_TCAL_ENABLE=1 \n " , imu ) ;
str . printf ( " INS%u_TCAL_TMIN=%.2f \n " , imu , temp_min . get ( ) ) ;
str . printf ( " INS%u_TCAL_TMAX=%.2f \n " , imu , temp_max . get ( ) ) ;
for ( uint8_t k = 0 ; k < 3 ; k + + ) {
const Vector3f & acc = accel_coeff [ k ] . get ( ) ;
const Vector3f & gyr = gyro_coeff [ k ] . get ( ) ;
str . printf ( " INS%u_TCAL_ACC%u_X=%f \n " , imu , k + 1 , acc . x ) ;
str . printf ( " INS%u_TCAL_ACC%u_Y=%f \n " , imu , k + 1 , acc . y ) ;
str . printf ( " INS%u_TCAL_ACC%u_Z=%f \n " , imu , k + 1 , acc . z ) ;
str . printf ( " INS%u_TCAL_GYR%u_X=%f \n " , imu , k + 1 , gyr . x ) ;
str . printf ( " INS%u_TCAL_GYR%u_Y=%f \n " , imu , k + 1 , gyr . y ) ;
str . printf ( " INS%u_TCAL_GYR%u_Z=%f \n " , imu , k + 1 , gyr . z ) ;
}
return ;
}
# endif
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str . printf ( " INS_TCAL%u_ENABLE=1 \n " , imu ) ;
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str . printf ( " INS_TCAL%u_TMIN=%.2f \n " , imu , temp_min . get ( ) ) ;
str . printf ( " INS_TCAL%u_TMAX=%.2f \n " , imu , temp_max . get ( ) ) ;
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for ( uint8_t k = 0 ; k < 3 ; k + + ) {
const Vector3f & acc = accel_coeff [ k ] . get ( ) ;
const Vector3f & gyr = gyro_coeff [ k ] . get ( ) ;
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str . printf ( " INS_TCAL%u_ACC%u_X=%f \n " , imu , k + 1 , acc . x ) ;
str . printf ( " INS_TCAL%u_ACC%u_Y=%f \n " , imu , k + 1 , acc . y ) ;
str . printf ( " INS_TCAL%u_ACC%u_Z=%f \n " , imu , k + 1 , acc . z ) ;
str . printf ( " INS_TCAL%u_GYR%u_X=%f \n " , imu , k + 1 , gyr . x ) ;
str . printf ( " INS_TCAL%u_GYR%u_Y=%f \n " , imu , k + 1 , gyr . y ) ;
str . printf ( " INS_TCAL%u_GYR%u_Z=%f \n " , imu , k + 1 , gyr . z ) ;
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}
}
/*
get a string representation of parameters that should be made
persistent across changes of firmware type
*/
void AP_InertialSensor : : get_persistent_params ( ExpandingString & str ) const
{
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bool save_options = false ;
if ( uint32_t ( tcal_options . get ( ) ) & uint32_t ( TCalOptions : : PERSIST_ACCEL_CAL ) ) {
save_options = true ;
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for ( uint8_t i = 0 ; i < ( INS_MAX_INSTANCES - INS_AUX_INSTANCES ) ; i + + ) {
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const uint8_t imu = i + 1 ;
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const Vector3f & aoff = _accel_offset ( i ) . get ( ) ;
const Vector3f & ascl = _accel_scale ( i ) . get ( ) ;
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char id [ 2 ] = " " ;
if ( i > 0 ) {
id [ 0 ] = ' 1 ' + i ;
}
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str . printf ( " INS_ACC%s_ID=%u \n " , id , unsigned ( _accel_id ( i ) . get ( ) ) ) ;
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str . printf ( " INS_ACC%sOFFS_X=%f \n " , id , aoff . x ) ;
str . printf ( " INS_ACC%sOFFS_Y=%f \n " , id , aoff . y ) ;
str . printf ( " INS_ACC%sOFFS_Z=%f \n " , id , aoff . z ) ;
str . printf ( " INS_ACC%sSCAL_X=%f \n " , id , ascl . x ) ;
str . printf ( " INS_ACC%sSCAL_Y=%f \n " , id , ascl . y ) ;
str . printf ( " INS_ACC%sSCAL_Z=%f \n " , id , ascl . z ) ;
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str . printf ( " INS_ACC%u_CALTEMP=%.2f \n " , imu , caltemp_accel ( i ) . get ( ) ) ;
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}
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# if INS_AUX_INSTANCES
for ( uint8_t i = 0 ; i < INS_AUX_INSTANCES ; i + + ) {
const uint8_t imu = i + ( INS_MAX_INSTANCES - INS_AUX_INSTANCES ) ;
const Vector3f & aoff = params [ i ] . _accel_offset . get ( ) ;
const Vector3f & ascl = params [ i ] . _accel_scale . get ( ) ;
str . printf ( " INS%u_ACC_ID=%u \n " , imu , unsigned ( params [ i ] . _accel_id . get ( ) ) ) ;
str . printf ( " INS%u_ACCOFFS_X=%f \n " , imu , aoff . x ) ;
str . printf ( " INS%u_ACCOFFS_Y=%f \n " , imu , aoff . y ) ;
str . printf ( " INS%u_ACCOFFS_Z=%f \n " , imu , aoff . z ) ;
str . printf ( " INS%u_ACCSCAL_X=%f \n " , imu , ascl . x ) ;
str . printf ( " INS%u_ACCSCAL_Y=%f \n " , imu , ascl . y ) ;
str . printf ( " INS%u_ACC_CALTEMP=%.2f \n " , imu , params [ i ] . caltemp_accel . get ( ) ) ;
}
# endif
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}
if ( uint32_t ( tcal_options . get ( ) ) & uint32_t ( TCalOptions : : PERSIST_TEMP_CAL ) ) {
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for ( auto & tc : tcal_old_param ) {
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tc . get_persistent_params ( str ) ;
}
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# if INS_AUX_INSTANCES
for ( uint8_t i = 0 ; i < INS_AUX_INSTANCES ; i + + ) {
params [ i ] . tcal . get_persistent_params ( str ) ;
}
# endif
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save_options = true ;
}
if ( save_options ) {
/*
we also have to save the TCAL_OPTIONS parameter so that
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future flashing of the bootloader doesn ' t cause an erase
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*/
str . printf ( " INS_TCAL_OPTIONS=%u \n " , unsigned ( tcal_options . get ( ) ) ) ;
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}
}
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# endif // HAL_INS_TEMPERATURE_CAL_ENABLE