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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/>.
*/
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# include "AP_OpticalFlow_config.h"
# if AP_OPTICALFLOW_CALIBRATOR_ENABLED
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# include "AP_OpticalFlow_Calibrator.h"
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# include <AP_InternalError/AP_InternalError.h>
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# include <GCS_MAVLink/GCS.h>
# include <AP_Logger/AP_Logger.h>
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# include <AP_AHRS/AP_AHRS.h>
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const uint32_t AP_OPTICALFLOW_CAL_TIMEOUT_SEC = 120 ; // calibration timesout after 120 seconds
const uint32_t AP_OPTICALFLOW_CAL_STATUSINTERVAL_SEC = 3 ; // status updates printed at 3 second intervals
const float AP_OPTICALFLOW_CAL_YAW_MAX_RADS = radians ( 20 ) ; // maximum yaw rotation (must be low to ensure good scaling)
const float AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS = radians ( 20 ) ; // minimum acceptable roll or pitch rotation
const float AP_OPTICALFLOW_CAL_SCALE_MIN = 0.20f ; // min acceptable scaling value. If resulting scaling is below this then the calibration fails
const float AP_OPTICALFLOW_CAL_SCALE_MAX = 4.0f ; // max acceptable scaling value. If resulting scaling is above this then the calibration fails
const float AP_OPTICALFLOW_CAL_FITNESS_THRESH = 0.5f ; // min acceptable fitness
const float AP_OPTICALFLOW_CAL_RMS_FAILED = 1.0e30 f ; // calc_mean_squared_residuals returns this value when it fails to calculate a good value
extern const AP_HAL : : HAL & hal ;
// start the calibration
void AP_OpticalFlow_Calibrator : : start ( )
{
// exit immediately if already running
if ( _cal_state = = CalState : : RUNNING ) {
return ;
}
_cal_state = CalState : : RUNNING ;
_start_time_ms = AP_HAL : : millis ( ) ;
// clear samples buffers
_cal_data [ 0 ] . num_samples = 0 ;
_cal_data [ 1 ] . num_samples = 0 ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " FlowCal: Started " ) ;
}
void AP_OpticalFlow_Calibrator : : stop ( )
{
// exit immediately if already stopped
if ( _cal_state = = CalState : : NOT_STARTED ) {
return ;
}
_cal_state = CalState : : NOT_STARTED ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " FlowCal: Stopped " ) ;
}
// update the state machine and calculate scaling
bool AP_OpticalFlow_Calibrator : : update ( )
{
// prefix for reporting
const char * prefix_str = " FlowCal: " ;
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( void ) prefix_str ; // in case !HAL_GCS_ENABLED
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// while running add samples
if ( _cal_state = = CalState : : RUNNING ) {
uint32_t now_ms = AP_HAL : : millis ( ) ;
uint32_t timestamp_ms ;
Vector2f flow_rate , body_rate , los_pred ;
if ( AP : : ahrs ( ) . getOptFlowSample ( timestamp_ms , flow_rate , body_rate , los_pred ) ) {
add_sample ( timestamp_ms , flow_rate , body_rate , los_pred ) ;
// while collecting samples display percentage complete
if ( now_ms - _last_report_ms > AP_OPTICALFLOW_CAL_STATUSINTERVAL_SEC * 1000UL ) {
_last_report_ms = now_ms ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s x:%d%% y:%d%% " ,
prefix_str ,
( int ) ( ( _cal_data [ 0 ] . num_samples * 100.0 / AP_OPTICALFLOW_CAL_MAX_SAMPLES ) ) ,
( int ) ( ( _cal_data [ 1 ] . num_samples * 100.0 / AP_OPTICALFLOW_CAL_MAX_SAMPLES ) ) ) ;
}
// advance state once sample buffers are full
if ( sample_buffers_full ( ) ) {
_cal_state = CalState : : READY_TO_CALIBRATE ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s samples collected " , prefix_str ) ;
}
}
// check for timeout
if ( now_ms - _start_time_ms > AP_OPTICALFLOW_CAL_TIMEOUT_SEC * 1000UL ) {
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s timeout " , prefix_str ) ;
_cal_state = CalState : : FAILED ;
}
}
// start calibration
if ( _cal_state = = CalState : : READY_TO_CALIBRATE ) {
// run calibration and mark failure or success
if ( run_calibration ( ) ) {
_cal_state = CalState : : SUCCESS ;
return true ;
} else {
_cal_state = CalState : : FAILED ;
}
}
// return indicating calibration is not complete
return false ;
}
// get final scaling values
// scaling values used during sample collection should be multiplied by these scalars
Vector2f AP_OpticalFlow_Calibrator : : get_scalars ( )
{
// return best scaling values
return Vector2f { _cal_data [ 0 ] . best_scalar , _cal_data [ 1 ] . best_scalar } ;
}
// add new sample to the calibrator
void AP_OpticalFlow_Calibrator : : add_sample ( uint32_t timestamp_ms , const Vector2f & flow_rate , const Vector2f & body_rate , const Vector2f & los_pred )
{
// return immediately if not running
if ( _cal_state ! = CalState : : RUNNING ) {
return ;
}
// check for duplicates
if ( timestamp_ms = = _last_sample_timestamp_ms ) {
return ;
}
_last_sample_timestamp_ms = timestamp_ms ;
// check yaw rotation is low
const Vector3f gyro = AP : : ahrs ( ) . get_gyro ( ) ;
if ( fabsf ( gyro . z ) > AP_OPTICALFLOW_CAL_YAW_MAX_RADS ) {
return ;
}
// check enough roll or pitch movement and record sample
const bool rates_x_sufficient = ( fabsf ( body_rate . x ) > = AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS ) & & ( fabsf ( flow_rate . x ) > = AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS ) ;
if ( rates_x_sufficient & & ( _cal_data [ 0 ] . num_samples < ARRAY_SIZE ( _cal_data [ 0 ] . samples ) ) ) {
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# if HAL_LOGGING_ENABLED
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log_sample ( 0 , _cal_data [ 0 ] . num_samples , flow_rate . x , body_rate . x , los_pred . x ) ;
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# endif
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_cal_data [ 0 ] . samples [ _cal_data [ 0 ] . num_samples ] . flow_rate = flow_rate . x ;
_cal_data [ 0 ] . samples [ _cal_data [ 0 ] . num_samples ] . body_rate = body_rate . x ;
_cal_data [ 0 ] . samples [ _cal_data [ 0 ] . num_samples ] . los_pred = los_pred . x ;
_cal_data [ 0 ] . num_samples + + ;
}
const bool rates_y_sufficient = ( fabsf ( body_rate . y ) > = AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS ) & & ( fabsf ( flow_rate . y ) > = AP_OPTICALFLOW_CAL_ROLLPITCH_MIN_RADS ) ;
if ( rates_y_sufficient & & ( _cal_data [ 1 ] . num_samples < ARRAY_SIZE ( _cal_data [ 1 ] . samples ) ) ) {
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# if HAL_LOGGING_ENABLED
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log_sample ( 1 , _cal_data [ 1 ] . num_samples , flow_rate . y , body_rate . y , los_pred . y ) ;
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# endif
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_cal_data [ 1 ] . samples [ _cal_data [ 1 ] . num_samples ] . flow_rate = flow_rate . y ;
_cal_data [ 1 ] . samples [ _cal_data [ 1 ] . num_samples ] . body_rate = body_rate . y ;
_cal_data [ 1 ] . samples [ _cal_data [ 1 ] . num_samples ] . los_pred = los_pred . y ;
_cal_data [ 1 ] . num_samples + + ;
}
}
// returns true once the sample buffer is full
bool AP_OpticalFlow_Calibrator : : sample_buffers_full ( ) const
{
return ( ( _cal_data [ 0 ] . num_samples > = ARRAY_SIZE ( _cal_data [ 0 ] . samples ) ) & & ( _cal_data [ 1 ] . num_samples > = ARRAY_SIZE ( _cal_data [ 1 ] . samples ) ) ) ;
}
// run calibration algorithm for both axis
// returns true on success and updates _cal_data[0,1].best_scale and best_scale_fitness
bool AP_OpticalFlow_Calibrator : : run_calibration ( )
{
// run calibration for x and y axis
const bool calx_res = calc_scalars ( 0 , _cal_data [ 0 ] . best_scalar , _cal_data [ 0 ] . best_scalar_fitness ) ;
const bool caly_res = calc_scalars ( 1 , _cal_data [ 1 ] . best_scalar , _cal_data [ 1 ] . best_scalar_fitness ) ;
return calx_res & & caly_res ;
}
// Run Gauss Newton fitting algorithm for all samples of the given axis
// returns a scalar and fitness (lower numbers mean a better result) in the arguments provided
bool AP_OpticalFlow_Calibrator : : calc_scalars ( uint8_t axis , float & scalar , float & fitness )
{
// prefix for reporting
const char * prefix_str = " FlowCal: " ;
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( void ) prefix_str ; // in case !HAL_GCS_ENABLED
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const char * axis_str = axis = = 0 ? " x " : " y " ;
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( void ) axis_str ; // in case !HAL_GCS_ENABLED
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// check we have samples
// this should never fail because this method should only be called once the sample buffer is full
const uint8_t num_samples = _cal_data [ axis ] . num_samples ;
if ( num_samples = = 0 ) {
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s failed because no samples " , prefix_str ) ;
return false ;
}
// calculate total absolute residual from all samples
float total_abs_residual = 0 ;
for ( uint8_t i = 0 ; i < num_samples ; i + + ) {
const sample_t & samplei = _cal_data [ axis ] . samples [ i ] ;
total_abs_residual + = fabsf ( calc_sample_residual ( samplei , 1.0 ) ) ;
}
// if there are no residuals then scaling is perfect
if ( is_zero ( total_abs_residual ) ) {
scalar = 1.0 ;
fitness = 0 ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s perfect scalar%s of 1.0 " , prefix_str , axis_str ) ;
return true ;
}
// for each sample calculate the residual and scalar that best reduces the residual
float best_scalar_total = 0 ;
for ( uint8_t i = 0 ; i < num_samples ; i + + ) {
float sample_best_scalar ;
const sample_t & samplei = _cal_data [ axis ] . samples [ i ] ;
if ( ! calc_sample_best_scalar ( samplei , sample_best_scalar ) ) {
// failed to find the best scalar for a single sample
// this should never happen because of checks when capturing samples
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s failed because of zero flow rate " , prefix_str ) ;
INTERNAL_ERROR ( AP_InternalError : : error_t : : flow_of_control ) ;
return false ;
}
const float sample_residual = calc_sample_residual ( samplei , 1.0 ) ;
best_scalar_total + = sample_best_scalar * fabsf ( sample_residual ) / total_abs_residual ;
}
// check for out of range results
if ( best_scalar_total < AP_OPTICALFLOW_CAL_SCALE_MIN ) {
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s scalar%s:%4.3f too low (<%3.1f) " , prefix_str , axis_str , ( double ) best_scalar_total , ( double ) AP_OPTICALFLOW_CAL_SCALE_MIN ) ;
return false ;
}
if ( best_scalar_total > AP_OPTICALFLOW_CAL_SCALE_MAX ) {
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s scalar%s:%4.3f too high (>%3.1f) " , prefix_str , axis_str , ( double ) best_scalar_total , ( double ) AP_OPTICALFLOW_CAL_SCALE_MAX ) ;
return false ;
}
// check for poor fitness
float fitness_new = calc_mean_squared_residuals ( axis , best_scalar_total ) ;
if ( fitness_new > AP_OPTICALFLOW_CAL_FITNESS_THRESH ) {
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s scalar%s:%4.3f fit:%4.3f too high (>%3.1f) " , prefix_str , axis_str , ( double ) scalar , ( double ) fitness_new , ( double ) AP_OPTICALFLOW_CAL_FITNESS_THRESH ) ;
return false ;
}
// success if fitness has improved
float fitness_orig = calc_mean_squared_residuals ( axis , 1.0 ) ;
if ( fitness_new < = fitness_orig ) {
scalar = best_scalar_total ;
fitness = fitness_new ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s scalar%s:%4.3f fit:%4.2f " , prefix_str , axis_str , ( double ) scalar , ( double ) fitness ) ;
return true ;
}
// failed to find a better scalar than 1.0
scalar = 1.0 ;
fitness = fitness_orig ;
GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " %s no better scalar%s:%4.3f (fit:%4.3f > orig:%4.3f) " , prefix_str , axis_str , ( double ) best_scalar_total , ( double ) fitness_new , ( double ) fitness_orig ) ;
return false ;
}
// calculate a single sample's residual
float AP_OpticalFlow_Calibrator : : calc_sample_residual ( const sample_t & sample , float scalar ) const
{
return ( sample . body_rate + ( ( sample . flow_rate * scalar ) - sample . los_pred ) ) ;
}
// calculate the scalar that minimises the residual for a single sample
// returns true on success and populates the best_scalar argument
bool AP_OpticalFlow_Calibrator : : calc_sample_best_scalar ( const sample_t & sample , float & best_scalar ) const
{
// if sample's flow_rate is zero scalar has no effect
// this should never happen because samples should have been checked before being added
if ( is_zero ( sample . flow_rate ) ) {
return false ;
}
best_scalar = ( sample . los_pred - sample . body_rate ) / sample . flow_rate ;
return true ;
}
// calculate mean squared residual for all samples of a single axis (0 or 1) given a scalar parameter
float AP_OpticalFlow_Calibrator : : calc_mean_squared_residuals ( uint8_t axis , float scalar ) const
{
// sanity check axis
if ( axis > = 2 ) {
return AP_OPTICALFLOW_CAL_RMS_FAILED ;
}
// calculate and sum residuals of each sample
float sum = 0.0f ;
uint16_t num_samples = 0 ;
for ( uint8_t i = 0 ; i < _cal_data [ axis ] . num_samples ; i + + ) {
sum + = sq ( calc_sample_residual ( _cal_data [ axis ] . samples [ i ] , scalar ) ) ;
num_samples + + ;
}
// return a huge residual if no samples
if ( num_samples = = 0 ) {
return AP_OPTICALFLOW_CAL_RMS_FAILED ;
}
sum / = num_samples ;
return sum ;
}
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# if HAL_LOGGING_ENABLED
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// log all samples
void AP_OpticalFlow_Calibrator : : log_sample ( uint8_t axis , uint8_t sample_num , float flow_rate , float body_rate , float los_pred )
{
// @LoggerMessage: OFCA
// @Description: Optical Flow Calibration sample
// @Field: TimeUS: Time since system startup
// @Field: Axis: Axis (X=0 Y=1)
// @Field: Num: Sample number
// @Field: FRate: Flow rate
// @Field: BRate: Body rate
// @Field: LPred: Los pred
AP_OpticalFlow: add some units to OFCA log message
Mainly just to get the instance column to make graphing axes easier
pbarker@fx:~/rc/ardupilot(master)$ mavlogdump.py logs/00000003.BIN --t FMTU | grep 251
2022-12-12 09:41:47.06: FMTU {TimeUS : 62248424, FmtType : 251, UnitIds : s#-???, MultIds : F00000}
pbarker@fx:~/rc/ardupilot(master)$ mavlogdump.py logs/00000003.BIN --t FMT | grep OFCA
2022-12-12 09:41:46.48: FMT {Type : 251, Length : 25, Name : OFCA, Format : QBBfff, Columns : TimeUS,Axis,Num,FRate,BRate,LPred}
MAV> graph OFCA[1].
OFCA[1].Axis OFCA[1].BRate OFCA[1].FRate OFCA[1].LPred OFCA[1].Num OFCA[1].TimeUS
MAV> graph OFCA[1].LPred
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AP : : logger ( ) . Write (
" OFCA " ,
" TimeUS,Axis,Num,FRate,BRate,LPred " ,
" s#-EEE " ,
" F00000 " ,
" QBBfff " ,
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AP_HAL : : micros64 ( ) ,
( unsigned ) axis ,
( unsigned ) sample_num ,
( double ) flow_rate ,
( double ) body_rate ,
( double ) los_pred ) ;
}
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# endif // HAL_LOGGING_ENABLED
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# endif // AP_OPTICALFLOW_CALIBRATOR_ENABLED