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# include <AP_HAL/AP_HAL.h>
# include "AP_NavEKF3.h"
# include "AP_NavEKF3_core.h"
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# include <AP_DAL/AP_DAL.h>
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/********************************************************
* RESET FUNCTIONS *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/********************************************************
* FUSE MEASURED_DATA *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/*
* Fuse true airspeed measurements using explicit algebraic equations generated with Matlab symbolic toolbox .
* The script file used to generate these and other equations in this filter can be found here :
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* https : //github.com/PX4/ecl/blob/master/matlab/scripts/Inertial%20Nav%20EKF/GenerateNavFilterEquations.m
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*/
void NavEKF3_core : : FuseAirspeed ( )
{
// declarations
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ftype vn ;
ftype ve ;
ftype vd ;
ftype vwn ;
ftype vwe ;
ftype SH_TAS [ 3 ] ;
ftype SK_TAS [ 2 ] ;
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Vector24 H_TAS = { } ;
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ftype VtasPred ;
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// copy required states to local variable names
vn = stateStruct . velocity . x ;
ve = stateStruct . velocity . y ;
vd = stateStruct . velocity . z ;
vwn = stateStruct . wind_vel . x ;
vwe = stateStruct . wind_vel . y ;
// calculate the predicted airspeed
VtasPred = norm ( ( ve - vwe ) , ( vn - vwn ) , vd ) ;
// perform fusion of True Airspeed measurement
if ( VtasPred > 1.0f )
{
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// calculate observation innovation and variance
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innovVtas = VtasPred - tasDataDelayed . tas ;
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// calculate observation jacobians
SH_TAS [ 0 ] = 1.0f / VtasPred ;
SH_TAS [ 1 ] = ( SH_TAS [ 0 ] * ( 2.0f * ve - 2.0f * vwe ) ) * 0.5f ;
SH_TAS [ 2 ] = ( SH_TAS [ 0 ] * ( 2.0f * vn - 2.0f * vwn ) ) * 0.5f ;
H_TAS [ 4 ] = SH_TAS [ 2 ] ;
H_TAS [ 5 ] = SH_TAS [ 1 ] ;
H_TAS [ 6 ] = vd * SH_TAS [ 0 ] ;
H_TAS [ 22 ] = - SH_TAS [ 2 ] ;
H_TAS [ 23 ] = - SH_TAS [ 1 ] ;
// calculate Kalman gains
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ftype temp = ( tasDataDelayed . tasVariance + SH_TAS [ 2 ] * ( P [ 4 ] [ 4 ] * SH_TAS [ 2 ] + P [ 5 ] [ 4 ] * SH_TAS [ 1 ] - P [ 22 ] [ 4 ] * SH_TAS [ 2 ] - P [ 23 ] [ 4 ] * SH_TAS [ 1 ] + P [ 6 ] [ 4 ] * vd * SH_TAS [ 0 ] ) + SH_TAS [ 1 ] * ( P [ 4 ] [ 5 ] * SH_TAS [ 2 ] + P [ 5 ] [ 5 ] * SH_TAS [ 1 ] - P [ 22 ] [ 5 ] * SH_TAS [ 2 ] - P [ 23 ] [ 5 ] * SH_TAS [ 1 ] + P [ 6 ] [ 5 ] * vd * SH_TAS [ 0 ] ) - SH_TAS [ 2 ] * ( P [ 4 ] [ 22 ] * SH_TAS [ 2 ] + P [ 5 ] [ 22 ] * SH_TAS [ 1 ] - P [ 22 ] [ 22 ] * SH_TAS [ 2 ] - P [ 23 ] [ 22 ] * SH_TAS [ 1 ] + P [ 6 ] [ 22 ] * vd * SH_TAS [ 0 ] ) - SH_TAS [ 1 ] * ( P [ 4 ] [ 23 ] * SH_TAS [ 2 ] + P [ 5 ] [ 23 ] * SH_TAS [ 1 ] - P [ 22 ] [ 23 ] * SH_TAS [ 2 ] - P [ 23 ] [ 23 ] * SH_TAS [ 1 ] + P [ 6 ] [ 23 ] * vd * SH_TAS [ 0 ] ) + vd * SH_TAS [ 0 ] * ( P [ 4 ] [ 6 ] * SH_TAS [ 2 ] + P [ 5 ] [ 6 ] * SH_TAS [ 1 ] - P [ 22 ] [ 6 ] * SH_TAS [ 2 ] - P [ 23 ] [ 6 ] * SH_TAS [ 1 ] + P [ 6 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ) ;
if ( temp > = tasDataDelayed . tasVariance ) {
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SK_TAS [ 0 ] = 1.0f / temp ;
faultStatus . bad_airspeed = false ;
} else {
// the calculation is badly conditioned, so we cannot perform fusion on this step
// we reset the covariance matrix and try again next measurement
CovarianceInit ( ) ;
faultStatus . bad_airspeed = true ;
return ;
}
SK_TAS [ 1 ] = SH_TAS [ 1 ] ;
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if ( tasDataDelayed . allowFusion & & ! airDataFusionWindOnly ) {
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Kfusion [ 0 ] = SK_TAS [ 0 ] * ( P [ 0 ] [ 4 ] * SH_TAS [ 2 ] - P [ 0 ] [ 22 ] * SH_TAS [ 2 ] + P [ 0 ] [ 5 ] * SK_TAS [ 1 ] - P [ 0 ] [ 23 ] * SK_TAS [ 1 ] + P [ 0 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 1 ] = SK_TAS [ 0 ] * ( P [ 1 ] [ 4 ] * SH_TAS [ 2 ] - P [ 1 ] [ 22 ] * SH_TAS [ 2 ] + P [ 1 ] [ 5 ] * SK_TAS [ 1 ] - P [ 1 ] [ 23 ] * SK_TAS [ 1 ] + P [ 1 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 2 ] = SK_TAS [ 0 ] * ( P [ 2 ] [ 4 ] * SH_TAS [ 2 ] - P [ 2 ] [ 22 ] * SH_TAS [ 2 ] + P [ 2 ] [ 5 ] * SK_TAS [ 1 ] - P [ 2 ] [ 23 ] * SK_TAS [ 1 ] + P [ 2 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 3 ] = SK_TAS [ 0 ] * ( P [ 3 ] [ 4 ] * SH_TAS [ 2 ] - P [ 3 ] [ 22 ] * SH_TAS [ 2 ] + P [ 3 ] [ 5 ] * SK_TAS [ 1 ] - P [ 3 ] [ 23 ] * SK_TAS [ 1 ] + P [ 3 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 4 ] = SK_TAS [ 0 ] * ( P [ 4 ] [ 4 ] * SH_TAS [ 2 ] - P [ 4 ] [ 22 ] * SH_TAS [ 2 ] + P [ 4 ] [ 5 ] * SK_TAS [ 1 ] - P [ 4 ] [ 23 ] * SK_TAS [ 1 ] + P [ 4 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 5 ] = SK_TAS [ 0 ] * ( P [ 5 ] [ 4 ] * SH_TAS [ 2 ] - P [ 5 ] [ 22 ] * SH_TAS [ 2 ] + P [ 5 ] [ 5 ] * SK_TAS [ 1 ] - P [ 5 ] [ 23 ] * SK_TAS [ 1 ] + P [ 5 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 6 ] = SK_TAS [ 0 ] * ( P [ 6 ] [ 4 ] * SH_TAS [ 2 ] - P [ 6 ] [ 22 ] * SH_TAS [ 2 ] + P [ 6 ] [ 5 ] * SK_TAS [ 1 ] - P [ 6 ] [ 23 ] * SK_TAS [ 1 ] + P [ 6 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 7 ] = SK_TAS [ 0 ] * ( P [ 7 ] [ 4 ] * SH_TAS [ 2 ] - P [ 7 ] [ 22 ] * SH_TAS [ 2 ] + P [ 7 ] [ 5 ] * SK_TAS [ 1 ] - P [ 7 ] [ 23 ] * SK_TAS [ 1 ] + P [ 7 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 8 ] = SK_TAS [ 0 ] * ( P [ 8 ] [ 4 ] * SH_TAS [ 2 ] - P [ 8 ] [ 22 ] * SH_TAS [ 2 ] + P [ 8 ] [ 5 ] * SK_TAS [ 1 ] - P [ 8 ] [ 23 ] * SK_TAS [ 1 ] + P [ 8 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 9 ] = SK_TAS [ 0 ] * ( P [ 9 ] [ 4 ] * SH_TAS [ 2 ] - P [ 9 ] [ 22 ] * SH_TAS [ 2 ] + P [ 9 ] [ 5 ] * SK_TAS [ 1 ] - P [ 9 ] [ 23 ] * SK_TAS [ 1 ] + P [ 9 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
} else {
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// zero indexes 0 to 9
zero_range ( & Kfusion [ 0 ] , 0 , 9 ) ;
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}
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if ( tasDataDelayed . allowFusion & & ! inhibitDelAngBiasStates & & ! airDataFusionWindOnly ) {
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Kfusion [ 10 ] = SK_TAS [ 0 ] * ( P [ 10 ] [ 4 ] * SH_TAS [ 2 ] - P [ 10 ] [ 22 ] * SH_TAS [ 2 ] + P [ 10 ] [ 5 ] * SK_TAS [ 1 ] - P [ 10 ] [ 23 ] * SK_TAS [ 1 ] + P [ 10 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 11 ] = SK_TAS [ 0 ] * ( P [ 11 ] [ 4 ] * SH_TAS [ 2 ] - P [ 11 ] [ 22 ] * SH_TAS [ 2 ] + P [ 11 ] [ 5 ] * SK_TAS [ 1 ] - P [ 11 ] [ 23 ] * SK_TAS [ 1 ] + P [ 11 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 12 ] = SK_TAS [ 0 ] * ( P [ 12 ] [ 4 ] * SH_TAS [ 2 ] - P [ 12 ] [ 22 ] * SH_TAS [ 2 ] + P [ 12 ] [ 5 ] * SK_TAS [ 1 ] - P [ 12 ] [ 23 ] * SK_TAS [ 1 ] + P [ 12 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
} else {
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// zero indexes 10 to 12
zero_range ( & Kfusion [ 0 ] , 10 , 12 ) ;
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}
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if ( tasDataDelayed . allowFusion & & ! inhibitDelVelBiasStates & & ! airDataFusionWindOnly ) {
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for ( uint8_t index = 0 ; index < 3 ; index + + ) {
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const uint8_t stateIndex = index + 13 ;
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if ( ! dvelBiasAxisInhibit [ index ] ) {
Kfusion [ stateIndex ] = SK_TAS [ 0 ] * ( P [ stateIndex ] [ 4 ] * SH_TAS [ 2 ] - P [ stateIndex ] [ 22 ] * SH_TAS [ 2 ] + P [ stateIndex ] [ 5 ] * SK_TAS [ 1 ] - P [ stateIndex ] [ 23 ] * SK_TAS [ 1 ] + P [ stateIndex ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
} else {
Kfusion [ stateIndex ] = 0.0f ;
}
}
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} else {
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// zero indexes 13 to 15
zero_range ( & Kfusion [ 0 ] , 13 , 15 ) ;
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}
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// zero Kalman gains to inhibit magnetic field state estimation
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if ( tasDataDelayed . allowFusion & & ! inhibitMagStates & & ! airDataFusionWindOnly ) {
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Kfusion [ 16 ] = SK_TAS [ 0 ] * ( P [ 16 ] [ 4 ] * SH_TAS [ 2 ] - P [ 16 ] [ 22 ] * SH_TAS [ 2 ] + P [ 16 ] [ 5 ] * SK_TAS [ 1 ] - P [ 16 ] [ 23 ] * SK_TAS [ 1 ] + P [ 16 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 17 ] = SK_TAS [ 0 ] * ( P [ 17 ] [ 4 ] * SH_TAS [ 2 ] - P [ 17 ] [ 22 ] * SH_TAS [ 2 ] + P [ 17 ] [ 5 ] * SK_TAS [ 1 ] - P [ 17 ] [ 23 ] * SK_TAS [ 1 ] + P [ 17 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 18 ] = SK_TAS [ 0 ] * ( P [ 18 ] [ 4 ] * SH_TAS [ 2 ] - P [ 18 ] [ 22 ] * SH_TAS [ 2 ] + P [ 18 ] [ 5 ] * SK_TAS [ 1 ] - P [ 18 ] [ 23 ] * SK_TAS [ 1 ] + P [ 18 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 19 ] = SK_TAS [ 0 ] * ( P [ 19 ] [ 4 ] * SH_TAS [ 2 ] - P [ 19 ] [ 22 ] * SH_TAS [ 2 ] + P [ 19 ] [ 5 ] * SK_TAS [ 1 ] - P [ 19 ] [ 23 ] * SK_TAS [ 1 ] + P [ 19 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 20 ] = SK_TAS [ 0 ] * ( P [ 20 ] [ 4 ] * SH_TAS [ 2 ] - P [ 20 ] [ 22 ] * SH_TAS [ 2 ] + P [ 20 ] [ 5 ] * SK_TAS [ 1 ] - P [ 20 ] [ 23 ] * SK_TAS [ 1 ] + P [ 20 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 21 ] = SK_TAS [ 0 ] * ( P [ 21 ] [ 4 ] * SH_TAS [ 2 ] - P [ 21 ] [ 22 ] * SH_TAS [ 2 ] + P [ 21 ] [ 5 ] * SK_TAS [ 1 ] - P [ 21 ] [ 23 ] * SK_TAS [ 1 ] + P [ 21 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
} else {
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// zero indexes 16 to 21
zero_range ( & Kfusion [ 0 ] , 16 , 21 ) ;
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}
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if ( tasDataDelayed . allowFusion & & ! inhibitWindStates ) {
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Kfusion [ 22 ] = SK_TAS [ 0 ] * ( P [ 22 ] [ 4 ] * SH_TAS [ 2 ] - P [ 22 ] [ 22 ] * SH_TAS [ 2 ] + P [ 22 ] [ 5 ] * SK_TAS [ 1 ] - P [ 22 ] [ 23 ] * SK_TAS [ 1 ] + P [ 22 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
Kfusion [ 23 ] = SK_TAS [ 0 ] * ( P [ 23 ] [ 4 ] * SH_TAS [ 2 ] - P [ 23 ] [ 22 ] * SH_TAS [ 2 ] + P [ 23 ] [ 5 ] * SK_TAS [ 1 ] - P [ 23 ] [ 23 ] * SK_TAS [ 1 ] + P [ 23 ] [ 6 ] * vd * SH_TAS [ 0 ] ) ;
} else {
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// zero indexes 22 to 23 = 2
zero_range ( & Kfusion [ 0 ] , 22 , 23 ) ;
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}
// calculate measurement innovation variance
varInnovVtas = 1.0f / SK_TAS [ 0 ] ;
// calculate the innovation consistency test ratio
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tasTestRatio = sq ( innovVtas ) / ( sq ( MAX ( 0.01f * ( ftype ) frontend - > _tasInnovGate , 1.0f ) ) * varInnovVtas ) ;
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// fail if the ratio is > 1, but don't fail if bad IMU data
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const bool isConsistent = ( tasTestRatio < 1.0f ) | | badIMUdata ;
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tasTimeout = ( imuSampleTime_ms - lastTasPassTime_ms ) > frontend - > tasRetryTime_ms ;
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if ( ! isConsistent ) {
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lastTasFailTime_ms = imuSampleTime_ms ;
} else {
lastTasFailTime_ms = 0 ;
}
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// test the ratio before fusing data, forcing fusion if airspeed and position are timed out as we have no choice but to try and use airspeed to constrain error growth
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if ( tasDataDelayed . allowFusion & & ( isConsistent | | ( tasTimeout & & posTimeout ) ) ) {
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// restart the counter
lastTasPassTime_ms = imuSampleTime_ms ;
// correct the state vector
for ( uint8_t j = 0 ; j < = stateIndexLim ; j + + ) {
statesArray [ j ] = statesArray [ j ] - Kfusion [ j ] * innovVtas ;
}
stateStruct . quat . normalize ( ) ;
// correct the covariance P = (I - K*H)*P
// take advantage of the empty columns in KH to reduce the
// number of operations
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = 3 ; j + + ) {
KH [ i ] [ j ] = 0.0f ;
}
for ( unsigned j = 4 ; j < = 6 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * H_TAS [ j ] ;
}
for ( unsigned j = 7 ; j < = 21 ; j + + ) {
KH [ i ] [ j ] = 0.0f ;
}
for ( unsigned j = 22 ; j < = 23 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * H_TAS [ j ] ;
}
}
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
ftype res = 0 ;
res + = KH [ i ] [ 4 ] * P [ 4 ] [ j ] ;
res + = KH [ i ] [ 5 ] * P [ 5 ] [ j ] ;
res + = KH [ i ] [ 6 ] * P [ 6 ] [ j ] ;
res + = KH [ i ] [ 22 ] * P [ 22 ] [ j ] ;
res + = KH [ i ] [ 23 ] * P [ 23 ] [ j ] ;
KHP [ i ] [ j ] = res ;
}
}
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
P [ i ] [ j ] = P [ i ] [ j ] - KHP [ i ] [ j ] ;
}
}
}
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// force the covariance matrix to be symmetrical and limit the variances to prevent ill-conditioning.
ForceSymmetry ( ) ;
ConstrainVariances ( ) ;
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}
}
// select fusion of true airspeed measurements
void NavEKF3_core : : SelectTasFusion ( )
{
// Check if the magnetometer has been fused on that time step and the filter is running at faster than 200 Hz
// If so, don't fuse measurements on this time step to reduce frame over-runs
// Only allow one time slip to prevent high rate magnetometer data locking out fusion of other measurements
if ( magFusePerformed & & dtIMUavg < 0.005f & & ! airSpdFusionDelayed ) {
airSpdFusionDelayed = true ;
return ;
} else {
airSpdFusionDelayed = false ;
}
// get true airspeed measurement
readAirSpdData ( ) ;
// if the filter is initialised, wind states are not inhibited and we have data to fuse, then perform TAS fusion
if ( tasDataToFuse & & statesInitialised & & ! inhibitWindStates ) {
FuseAirspeed ( ) ;
prevTasStep_ms = imuSampleTime_ms ;
}
}
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// select fusion of synthetic sideslip measurements or body frame drag
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// synthetic sidelip fusion only works for fixed wing aircraft and relies on the average sideslip being close to zero
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// body frame drag only works for bluff body multi rotor vehices with thrust forces aligned with the Z axis
// it requires a stable wind for best results and should not be used for aerobatic flight
void NavEKF3_core : : SelectBetaDragFusion ( )
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{
// Check if the magnetometer has been fused on that time step and the filter is running at faster than 200 Hz
// If so, don't fuse measurements on this time step to reduce frame over-runs
// Only allow one time slip to prevent high rate magnetometer data preventing fusion of other measurements
if ( magFusePerformed & & dtIMUavg < 0.005f & & ! sideSlipFusionDelayed ) {
sideSlipFusionDelayed = true ;
return ;
} else {
sideSlipFusionDelayed = false ;
}
// set true when the fusion time interval has triggered
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bool f_timeTrigger = ( ( imuSampleTime_ms - prevBetaDragStep_ms ) > = frontend - > betaAvg_ms ) ;
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// use of air data to constrain drift is necessary if we have limited sensor data or are doing inertial dead reckoning
bool is_dead_reckoning = ( ( imuSampleTime_ms - lastPosPassTime_ms ) > frontend - > deadReckonDeclare_ms ) & & ( ( imuSampleTime_ms - lastVelPassTime_ms ) > frontend - > deadReckonDeclare_ms ) ;
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const bool noYawSensor = ! use_compass ( ) & & ! using_noncompass_for_yaw ( ) ;
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const bool f_required = ( noYawSensor & & ( frontend - > _betaMask & ( 1 < < 1 ) ) ) | | is_dead_reckoning ;
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// set true when sideslip fusion is feasible (requires zero sideslip assumption to be valid and use of wind states)
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const bool f_beta_feasible = ( assume_zero_sideslip ( ) & & ! inhibitWindStates ) ;
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// use synthetic sideslip fusion if feasible, required and enough time has lapsed since the last fusion
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if ( f_beta_feasible & & f_timeTrigger ) {
// unless air data is required to constrain drift, it is only used to update wind state estimates
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if ( f_required | | ( frontend - > _betaMask & ( 1 < < 0 ) ) ) {
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// we are required to correct all states
airDataFusionWindOnly = false ;
} else {
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// we are required to correct only wind states
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airDataFusionWindOnly = true ;
}
// Fuse estimated airspeed to aid wind estimation
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if ( usingDefaultAirspeed ) {
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FuseAirspeed ( ) ;
}
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FuseSideslip ( ) ;
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prevBetaDragStep_ms = imuSampleTime_ms ;
}
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# if EK3_FEATURE_DRAG_FUSION
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// fusion of XY body frame aero specific forces is done at a slower rate and only if alternative methods of wind estimation are not available
if ( ! inhibitWindStates & & storedDrag . recall ( dragSampleDelayed , imuDataDelayed . time_ms ) ) {
FuseDragForces ( ) ;
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}
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dragTimeout = ( imuSampleTime_ms - lastDragPassTime_ms ) > frontend - > dragFailTimeLimit_ms ;
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# endif
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}
/*
* Fuse sythetic sideslip measurement of zero using explicit algebraic equations generated with Matlab symbolic toolbox .
* The script file used to generate these and other equations in this filter can be found here :
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* https : //github.com/PX4/ecl/blob/master/matlab/scripts/Inertial%20Nav%20EKF/GenerateNavFilterEquations.m
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*/
void NavEKF3_core : : FuseSideslip ( )
{
// declarations
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ftype q0 ;
ftype q1 ;
ftype q2 ;
ftype q3 ;
ftype vn ;
ftype ve ;
ftype vd ;
ftype vwn ;
ftype vwe ;
const ftype R_BETA = 0.03f ; // assume a sideslip angle RMS of ~10 deg
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Vector13 SH_BETA ;
Vector8 SK_BETA ;
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Vector3F vel_rel_wind ;
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Vector24 H_BETA ;
// copy required states to local variable names
q0 = stateStruct . quat [ 0 ] ;
q1 = stateStruct . quat [ 1 ] ;
q2 = stateStruct . quat [ 2 ] ;
q3 = stateStruct . quat [ 3 ] ;
vn = stateStruct . velocity . x ;
ve = stateStruct . velocity . y ;
vd = stateStruct . velocity . z ;
vwn = stateStruct . wind_vel . x ;
vwe = stateStruct . wind_vel . y ;
// calculate predicted wind relative velocity in NED
vel_rel_wind . x = vn - vwn ;
vel_rel_wind . y = ve - vwe ;
vel_rel_wind . z = vd ;
// rotate into body axes
vel_rel_wind = prevTnb * vel_rel_wind ;
// perform fusion of assumed sideslip = 0
if ( vel_rel_wind . x > 5.0f )
{
// Calculate observation jacobians
SH_BETA [ 0 ] = ( vn - vwn ) * ( sq ( q0 ) + sq ( q1 ) - sq ( q2 ) - sq ( q3 ) ) - vd * ( 2 * q0 * q2 - 2 * q1 * q3 ) + ( ve - vwe ) * ( 2 * q0 * q3 + 2 * q1 * q2 ) ;
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if ( fabsF ( SH_BETA [ 0 ] ) < = 1e-9 f ) {
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faultStatus . bad_sideslip = true ;
return ;
} else {
faultStatus . bad_sideslip = false ;
}
SH_BETA [ 1 ] = ( ve - vwe ) * ( sq ( q0 ) - sq ( q1 ) + sq ( q2 ) - sq ( q3 ) ) + vd * ( 2 * q0 * q1 + 2 * q2 * q3 ) - ( vn - vwn ) * ( 2 * q0 * q3 - 2 * q1 * q2 ) ;
SH_BETA [ 2 ] = vn - vwn ;
SH_BETA [ 3 ] = ve - vwe ;
SH_BETA [ 4 ] = 1 / sq ( SH_BETA [ 0 ] ) ;
SH_BETA [ 5 ] = 1 / SH_BETA [ 0 ] ;
SH_BETA [ 6 ] = SH_BETA [ 5 ] * ( sq ( q0 ) - sq ( q1 ) + sq ( q2 ) - sq ( q3 ) ) ;
SH_BETA [ 7 ] = sq ( q0 ) + sq ( q1 ) - sq ( q2 ) - sq ( q3 ) ;
SH_BETA [ 8 ] = 2 * q0 * SH_BETA [ 3 ] - 2 * q3 * SH_BETA [ 2 ] + 2 * q1 * vd ;
SH_BETA [ 9 ] = 2 * q0 * SH_BETA [ 2 ] + 2 * q3 * SH_BETA [ 3 ] - 2 * q2 * vd ;
SH_BETA [ 10 ] = 2 * q2 * SH_BETA [ 2 ] - 2 * q1 * SH_BETA [ 3 ] + 2 * q0 * vd ;
SH_BETA [ 11 ] = 2 * q1 * SH_BETA [ 2 ] + 2 * q2 * SH_BETA [ 3 ] + 2 * q3 * vd ;
SH_BETA [ 12 ] = 2 * q0 * q3 ;
H_BETA [ 0 ] = SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ;
H_BETA [ 1 ] = SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ;
H_BETA [ 2 ] = SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ;
H_BETA [ 3 ] = - SH_BETA [ 5 ] * SH_BETA [ 9 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ;
H_BETA [ 4 ] = - SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ;
H_BETA [ 5 ] = SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ;
H_BETA [ 6 ] = SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ;
for ( uint8_t i = 7 ; i < = 21 ; i + + ) {
H_BETA [ i ] = 0.0f ;
}
H_BETA [ 22 ] = SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ;
H_BETA [ 23 ] = SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) - SH_BETA [ 6 ] ;
// Calculate Kalman gains
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ftype temp = ( R_BETA - ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) * ( P [ 22 ] [ 4 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) - P [ 4 ] [ 4 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) + P [ 5 ] [ 4 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) - P [ 23 ] [ 4 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) + P [ 0 ] [ 4 ] * ( SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ) + P [ 1 ] [ 4 ] * ( SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ) + P [ 2 ] [ 4 ] * ( SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ) - P [ 3 ] [ 4 ] * ( SH_BETA [ 5 ] * SH_BETA [ 9 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ) + P [ 6 ] [ 4 ] * ( SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ) ) + ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) * ( P [ 22 ] [ 22 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) - P [ 4 ] [ 22 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) + P [ 5 ] [ 22 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) - P [ 23 ] [ 22 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) + P [ 0 ] [ 22 ] * ( SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ) + P [ 1 ] [ 22 ] * ( SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ) + P [ 2 ] [ 22 ] * ( SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ) - P [ 3 ] [ 22 ] * ( SH_BETA [ 5 ] * SH_BETA [ 9 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ) + P [ 6 ] [ 22 ] * ( SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ) ) + ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) * ( P [ 22 ] [ 5 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) - P [ 4 ] [ 5 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) + P [ 5 ] [ 5 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) - P [ 23 ] [ 5 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) + P [ 0 ] [ 5 ] * ( SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ) + P [ 1 ] [ 5 ] * ( SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ) + P [ 2 ] [ 5 ] * ( SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ) - P [ 3 ] [ 5 ] * ( SH_BETA [ 5 ] * SH_BETA [ 9 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ) + P [ 6 ] [ 5 ] * ( SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ) ) - ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) * ( P [ 22 ] [ 23 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) - P [ 4 ] [ 23 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) + P [ 5 ] [ 23 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) - P [ 23 ] [ 23 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) + P [ 0 ] [ 23 ] * ( SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ) + P [ 1 ] [ 23 ] * ( SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ) + P [ 2 ] [ 23 ] * ( SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ) - P [ 3 ] [ 23 ] * ( SH_BETA [ 5 ] * SH_BETA [ 9 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ) + P [ 6 ] [ 23 ] * ( SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ) ) + ( SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ) * ( P [ 22 ] [ 0 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) - P [ 4 ] [ 0 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) + P [ 5 ] [ 0 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) - P [ 23 ] [ 0 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) + P [ 0 ] [ 0 ] * ( SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ) + P [ 1 ] [ 0 ] * ( SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ) + P [ 2 ] [ 0 ] * ( SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ) - P [ 3 ] [ 0 ] * ( SH_BETA [ 5 ] * SH_BETA [ 9 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ) + P [ 6 ] [ 0 ] * ( SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ) ) + ( SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ) * ( P [ 22 ] [ 1 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) - P [ 4 ] [ 1 ] * ( SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ) + P [ 5 ] [ 1 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ) - P [ 23 ] [ 1 ] * ( SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_B
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if ( temp > = R_BETA ) {
SK_BETA [ 0 ] = 1.0f / temp ;
faultStatus . bad_sideslip = false ;
} else {
// the calculation is badly conditioned, so we cannot perform fusion on this step
// we reset the covariance matrix and try again next measurement
CovarianceInit ( ) ;
faultStatus . bad_sideslip = true ;
return ;
}
SK_BETA [ 1 ] = SH_BETA [ 5 ] * ( SH_BETA [ 12 ] - 2 * q1 * q2 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 7 ] ;
SK_BETA [ 2 ] = SH_BETA [ 6 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( SH_BETA [ 12 ] + 2 * q1 * q2 ) ;
SK_BETA [ 3 ] = SH_BETA [ 5 ] * ( 2 * q0 * q1 + 2 * q2 * q3 ) + SH_BETA [ 1 ] * SH_BETA [ 4 ] * ( 2 * q0 * q2 - 2 * q1 * q3 ) ;
SK_BETA [ 4 ] = SH_BETA [ 5 ] * SH_BETA [ 10 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 11 ] ;
SK_BETA [ 5 ] = SH_BETA [ 5 ] * SH_BETA [ 8 ] - SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 9 ] ;
SK_BETA [ 6 ] = SH_BETA [ 5 ] * SH_BETA [ 11 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 10 ] ;
SK_BETA [ 7 ] = SH_BETA [ 5 ] * SH_BETA [ 9 ] + SH_BETA [ 1 ] * SH_BETA [ 4 ] * SH_BETA [ 8 ] ;
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if ( ! airDataFusionWindOnly ) {
Kfusion [ 0 ] = SK_BETA [ 0 ] * ( P [ 0 ] [ 0 ] * SK_BETA [ 5 ] + P [ 0 ] [ 1 ] * SK_BETA [ 4 ] - P [ 0 ] [ 4 ] * SK_BETA [ 1 ] + P [ 0 ] [ 5 ] * SK_BETA [ 2 ] + P [ 0 ] [ 2 ] * SK_BETA [ 6 ] + P [ 0 ] [ 6 ] * SK_BETA [ 3 ] - P [ 0 ] [ 3 ] * SK_BETA [ 7 ] + P [ 0 ] [ 22 ] * SK_BETA [ 1 ] - P [ 0 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 1 ] = SK_BETA [ 0 ] * ( P [ 1 ] [ 0 ] * SK_BETA [ 5 ] + P [ 1 ] [ 1 ] * SK_BETA [ 4 ] - P [ 1 ] [ 4 ] * SK_BETA [ 1 ] + P [ 1 ] [ 5 ] * SK_BETA [ 2 ] + P [ 1 ] [ 2 ] * SK_BETA [ 6 ] + P [ 1 ] [ 6 ] * SK_BETA [ 3 ] - P [ 1 ] [ 3 ] * SK_BETA [ 7 ] + P [ 1 ] [ 22 ] * SK_BETA [ 1 ] - P [ 1 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 2 ] = SK_BETA [ 0 ] * ( P [ 2 ] [ 0 ] * SK_BETA [ 5 ] + P [ 2 ] [ 1 ] * SK_BETA [ 4 ] - P [ 2 ] [ 4 ] * SK_BETA [ 1 ] + P [ 2 ] [ 5 ] * SK_BETA [ 2 ] + P [ 2 ] [ 2 ] * SK_BETA [ 6 ] + P [ 2 ] [ 6 ] * SK_BETA [ 3 ] - P [ 2 ] [ 3 ] * SK_BETA [ 7 ] + P [ 2 ] [ 22 ] * SK_BETA [ 1 ] - P [ 2 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 3 ] = SK_BETA [ 0 ] * ( P [ 3 ] [ 0 ] * SK_BETA [ 5 ] + P [ 3 ] [ 1 ] * SK_BETA [ 4 ] - P [ 3 ] [ 4 ] * SK_BETA [ 1 ] + P [ 3 ] [ 5 ] * SK_BETA [ 2 ] + P [ 3 ] [ 2 ] * SK_BETA [ 6 ] + P [ 3 ] [ 6 ] * SK_BETA [ 3 ] - P [ 3 ] [ 3 ] * SK_BETA [ 7 ] + P [ 3 ] [ 22 ] * SK_BETA [ 1 ] - P [ 3 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 4 ] = SK_BETA [ 0 ] * ( P [ 4 ] [ 0 ] * SK_BETA [ 5 ] + P [ 4 ] [ 1 ] * SK_BETA [ 4 ] - P [ 4 ] [ 4 ] * SK_BETA [ 1 ] + P [ 4 ] [ 5 ] * SK_BETA [ 2 ] + P [ 4 ] [ 2 ] * SK_BETA [ 6 ] + P [ 4 ] [ 6 ] * SK_BETA [ 3 ] - P [ 4 ] [ 3 ] * SK_BETA [ 7 ] + P [ 4 ] [ 22 ] * SK_BETA [ 1 ] - P [ 4 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 5 ] = SK_BETA [ 0 ] * ( P [ 5 ] [ 0 ] * SK_BETA [ 5 ] + P [ 5 ] [ 1 ] * SK_BETA [ 4 ] - P [ 5 ] [ 4 ] * SK_BETA [ 1 ] + P [ 5 ] [ 5 ] * SK_BETA [ 2 ] + P [ 5 ] [ 2 ] * SK_BETA [ 6 ] + P [ 5 ] [ 6 ] * SK_BETA [ 3 ] - P [ 5 ] [ 3 ] * SK_BETA [ 7 ] + P [ 5 ] [ 22 ] * SK_BETA [ 1 ] - P [ 5 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 6 ] = SK_BETA [ 0 ] * ( P [ 6 ] [ 0 ] * SK_BETA [ 5 ] + P [ 6 ] [ 1 ] * SK_BETA [ 4 ] - P [ 6 ] [ 4 ] * SK_BETA [ 1 ] + P [ 6 ] [ 5 ] * SK_BETA [ 2 ] + P [ 6 ] [ 2 ] * SK_BETA [ 6 ] + P [ 6 ] [ 6 ] * SK_BETA [ 3 ] - P [ 6 ] [ 3 ] * SK_BETA [ 7 ] + P [ 6 ] [ 22 ] * SK_BETA [ 1 ] - P [ 6 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 7 ] = SK_BETA [ 0 ] * ( P [ 7 ] [ 0 ] * SK_BETA [ 5 ] + P [ 7 ] [ 1 ] * SK_BETA [ 4 ] - P [ 7 ] [ 4 ] * SK_BETA [ 1 ] + P [ 7 ] [ 5 ] * SK_BETA [ 2 ] + P [ 7 ] [ 2 ] * SK_BETA [ 6 ] + P [ 7 ] [ 6 ] * SK_BETA [ 3 ] - P [ 7 ] [ 3 ] * SK_BETA [ 7 ] + P [ 7 ] [ 22 ] * SK_BETA [ 1 ] - P [ 7 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 8 ] = SK_BETA [ 0 ] * ( P [ 8 ] [ 0 ] * SK_BETA [ 5 ] + P [ 8 ] [ 1 ] * SK_BETA [ 4 ] - P [ 8 ] [ 4 ] * SK_BETA [ 1 ] + P [ 8 ] [ 5 ] * SK_BETA [ 2 ] + P [ 8 ] [ 2 ] * SK_BETA [ 6 ] + P [ 8 ] [ 6 ] * SK_BETA [ 3 ] - P [ 8 ] [ 3 ] * SK_BETA [ 7 ] + P [ 8 ] [ 22 ] * SK_BETA [ 1 ] - P [ 8 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 9 ] = SK_BETA [ 0 ] * ( P [ 9 ] [ 0 ] * SK_BETA [ 5 ] + P [ 9 ] [ 1 ] * SK_BETA [ 4 ] - P [ 9 ] [ 4 ] * SK_BETA [ 1 ] + P [ 9 ] [ 5 ] * SK_BETA [ 2 ] + P [ 9 ] [ 2 ] * SK_BETA [ 6 ] + P [ 9 ] [ 6 ] * SK_BETA [ 3 ] - P [ 9 ] [ 3 ] * SK_BETA [ 7 ] + P [ 9 ] [ 22 ] * SK_BETA [ 1 ] - P [ 9 ] [ 23 ] * SK_BETA [ 2 ] ) ;
} else {
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// zero indexes 0 to 9
zero_range ( & Kfusion [ 0 ] , 0 , 9 ) ;
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}
if ( ! inhibitDelAngBiasStates & & ! airDataFusionWindOnly ) {
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Kfusion [ 10 ] = SK_BETA [ 0 ] * ( P [ 10 ] [ 0 ] * SK_BETA [ 5 ] + P [ 10 ] [ 1 ] * SK_BETA [ 4 ] - P [ 10 ] [ 4 ] * SK_BETA [ 1 ] + P [ 10 ] [ 5 ] * SK_BETA [ 2 ] + P [ 10 ] [ 2 ] * SK_BETA [ 6 ] + P [ 10 ] [ 6 ] * SK_BETA [ 3 ] - P [ 10 ] [ 3 ] * SK_BETA [ 7 ] + P [ 10 ] [ 22 ] * SK_BETA [ 1 ] - P [ 10 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 11 ] = SK_BETA [ 0 ] * ( P [ 11 ] [ 0 ] * SK_BETA [ 5 ] + P [ 11 ] [ 1 ] * SK_BETA [ 4 ] - P [ 11 ] [ 4 ] * SK_BETA [ 1 ] + P [ 11 ] [ 5 ] * SK_BETA [ 2 ] + P [ 11 ] [ 2 ] * SK_BETA [ 6 ] + P [ 11 ] [ 6 ] * SK_BETA [ 3 ] - P [ 11 ] [ 3 ] * SK_BETA [ 7 ] + P [ 11 ] [ 22 ] * SK_BETA [ 1 ] - P [ 11 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 12 ] = SK_BETA [ 0 ] * ( P [ 12 ] [ 0 ] * SK_BETA [ 5 ] + P [ 12 ] [ 1 ] * SK_BETA [ 4 ] - P [ 12 ] [ 4 ] * SK_BETA [ 1 ] + P [ 12 ] [ 5 ] * SK_BETA [ 2 ] + P [ 12 ] [ 2 ] * SK_BETA [ 6 ] + P [ 12 ] [ 6 ] * SK_BETA [ 3 ] - P [ 12 ] [ 3 ] * SK_BETA [ 7 ] + P [ 12 ] [ 22 ] * SK_BETA [ 1 ] - P [ 12 ] [ 23 ] * SK_BETA [ 2 ] ) ;
} else {
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// zero indexes 10 to 12 = 3
zero_range ( & Kfusion [ 0 ] , 10 , 12 ) ;
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}
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if ( ! inhibitDelVelBiasStates & & ! airDataFusionWindOnly ) {
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for ( uint8_t index = 0 ; index < 3 ; index + + ) {
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const uint8_t stateIndex = index + 13 ;
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if ( ! dvelBiasAxisInhibit [ index ] ) {
Kfusion [ stateIndex ] = SK_BETA [ 0 ] * ( P [ stateIndex ] [ 0 ] * SK_BETA [ 5 ] + P [ stateIndex ] [ 1 ] * SK_BETA [ 4 ] - P [ stateIndex ] [ 4 ] * SK_BETA [ 1 ] + P [ stateIndex ] [ 5 ] * SK_BETA [ 2 ] + P [ stateIndex ] [ 2 ] * SK_BETA [ 6 ] + P [ stateIndex ] [ 6 ] * SK_BETA [ 3 ] - P [ stateIndex ] [ 3 ] * SK_BETA [ 7 ] + P [ stateIndex ] [ 22 ] * SK_BETA [ 1 ] - P [ stateIndex ] [ 23 ] * SK_BETA [ 2 ] ) ;
} else {
Kfusion [ stateIndex ] = 0.0f ;
}
}
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} else {
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// zero indexes 13 to 15
zero_range ( & Kfusion [ 0 ] , 13 , 15 ) ;
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}
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// zero Kalman gains to inhibit magnetic field state estimation
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if ( ! inhibitMagStates & & ! airDataFusionWindOnly ) {
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Kfusion [ 16 ] = SK_BETA [ 0 ] * ( P [ 16 ] [ 0 ] * SK_BETA [ 5 ] + P [ 16 ] [ 1 ] * SK_BETA [ 4 ] - P [ 16 ] [ 4 ] * SK_BETA [ 1 ] + P [ 16 ] [ 5 ] * SK_BETA [ 2 ] + P [ 16 ] [ 2 ] * SK_BETA [ 6 ] + P [ 16 ] [ 6 ] * SK_BETA [ 3 ] - P [ 16 ] [ 3 ] * SK_BETA [ 7 ] + P [ 16 ] [ 22 ] * SK_BETA [ 1 ] - P [ 16 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 17 ] = SK_BETA [ 0 ] * ( P [ 17 ] [ 0 ] * SK_BETA [ 5 ] + P [ 17 ] [ 1 ] * SK_BETA [ 4 ] - P [ 17 ] [ 4 ] * SK_BETA [ 1 ] + P [ 17 ] [ 5 ] * SK_BETA [ 2 ] + P [ 17 ] [ 2 ] * SK_BETA [ 6 ] + P [ 17 ] [ 6 ] * SK_BETA [ 3 ] - P [ 17 ] [ 3 ] * SK_BETA [ 7 ] + P [ 17 ] [ 22 ] * SK_BETA [ 1 ] - P [ 17 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 18 ] = SK_BETA [ 0 ] * ( P [ 18 ] [ 0 ] * SK_BETA [ 5 ] + P [ 18 ] [ 1 ] * SK_BETA [ 4 ] - P [ 18 ] [ 4 ] * SK_BETA [ 1 ] + P [ 18 ] [ 5 ] * SK_BETA [ 2 ] + P [ 18 ] [ 2 ] * SK_BETA [ 6 ] + P [ 18 ] [ 6 ] * SK_BETA [ 3 ] - P [ 18 ] [ 3 ] * SK_BETA [ 7 ] + P [ 18 ] [ 22 ] * SK_BETA [ 1 ] - P [ 18 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 19 ] = SK_BETA [ 0 ] * ( P [ 19 ] [ 0 ] * SK_BETA [ 5 ] + P [ 19 ] [ 1 ] * SK_BETA [ 4 ] - P [ 19 ] [ 4 ] * SK_BETA [ 1 ] + P [ 19 ] [ 5 ] * SK_BETA [ 2 ] + P [ 19 ] [ 2 ] * SK_BETA [ 6 ] + P [ 19 ] [ 6 ] * SK_BETA [ 3 ] - P [ 19 ] [ 3 ] * SK_BETA [ 7 ] + P [ 19 ] [ 22 ] * SK_BETA [ 1 ] - P [ 19 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 20 ] = SK_BETA [ 0 ] * ( P [ 20 ] [ 0 ] * SK_BETA [ 5 ] + P [ 20 ] [ 1 ] * SK_BETA [ 4 ] - P [ 20 ] [ 4 ] * SK_BETA [ 1 ] + P [ 20 ] [ 5 ] * SK_BETA [ 2 ] + P [ 20 ] [ 2 ] * SK_BETA [ 6 ] + P [ 20 ] [ 6 ] * SK_BETA [ 3 ] - P [ 20 ] [ 3 ] * SK_BETA [ 7 ] + P [ 20 ] [ 22 ] * SK_BETA [ 1 ] - P [ 20 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 21 ] = SK_BETA [ 0 ] * ( P [ 21 ] [ 0 ] * SK_BETA [ 5 ] + P [ 21 ] [ 1 ] * SK_BETA [ 4 ] - P [ 21 ] [ 4 ] * SK_BETA [ 1 ] + P [ 21 ] [ 5 ] * SK_BETA [ 2 ] + P [ 21 ] [ 2 ] * SK_BETA [ 6 ] + P [ 21 ] [ 6 ] * SK_BETA [ 3 ] - P [ 21 ] [ 3 ] * SK_BETA [ 7 ] + P [ 21 ] [ 22 ] * SK_BETA [ 1 ] - P [ 21 ] [ 23 ] * SK_BETA [ 2 ] ) ;
} else {
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// zero indexes 16 to 21
zero_range ( & Kfusion [ 0 ] , 16 , 21 ) ;
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}
if ( ! inhibitWindStates ) {
Kfusion [ 22 ] = SK_BETA [ 0 ] * ( P [ 22 ] [ 0 ] * SK_BETA [ 5 ] + P [ 22 ] [ 1 ] * SK_BETA [ 4 ] - P [ 22 ] [ 4 ] * SK_BETA [ 1 ] + P [ 22 ] [ 5 ] * SK_BETA [ 2 ] + P [ 22 ] [ 2 ] * SK_BETA [ 6 ] + P [ 22 ] [ 6 ] * SK_BETA [ 3 ] - P [ 22 ] [ 3 ] * SK_BETA [ 7 ] + P [ 22 ] [ 22 ] * SK_BETA [ 1 ] - P [ 22 ] [ 23 ] * SK_BETA [ 2 ] ) ;
Kfusion [ 23 ] = SK_BETA [ 0 ] * ( P [ 23 ] [ 0 ] * SK_BETA [ 5 ] + P [ 23 ] [ 1 ] * SK_BETA [ 4 ] - P [ 23 ] [ 4 ] * SK_BETA [ 1 ] + P [ 23 ] [ 5 ] * SK_BETA [ 2 ] + P [ 23 ] [ 2 ] * SK_BETA [ 6 ] + P [ 23 ] [ 6 ] * SK_BETA [ 3 ] - P [ 23 ] [ 3 ] * SK_BETA [ 7 ] + P [ 23 ] [ 22 ] * SK_BETA [ 1 ] - P [ 23 ] [ 23 ] * SK_BETA [ 2 ] ) ;
} else {
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// zero indexes 22 to 23
zero_range ( & Kfusion [ 0 ] , 22 , 23 ) ;
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}
// calculate predicted sideslip angle and innovation using small angle approximation
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innovBeta = constrain_ftype ( vel_rel_wind . y / vel_rel_wind . x , - 0.5f , 0.5f ) ;
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// correct the state vector
for ( uint8_t j = 0 ; j < = stateIndexLim ; j + + ) {
statesArray [ j ] = statesArray [ j ] - Kfusion [ j ] * innovBeta ;
}
stateStruct . quat . normalize ( ) ;
// correct the covariance P = (I - K*H)*P
// take advantage of the empty columns in KH to reduce the
// number of operations
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = 6 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * H_BETA [ j ] ;
}
for ( unsigned j = 7 ; j < = 21 ; j + + ) {
KH [ i ] [ j ] = 0.0f ;
}
for ( unsigned j = 22 ; j < = 23 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * H_BETA [ j ] ;
}
}
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
ftype res = 0 ;
res + = KH [ i ] [ 0 ] * P [ 0 ] [ j ] ;
res + = KH [ i ] [ 1 ] * P [ 1 ] [ j ] ;
res + = KH [ i ] [ 2 ] * P [ 2 ] [ j ] ;
res + = KH [ i ] [ 3 ] * P [ 3 ] [ j ] ;
res + = KH [ i ] [ 4 ] * P [ 4 ] [ j ] ;
res + = KH [ i ] [ 5 ] * P [ 5 ] [ j ] ;
res + = KH [ i ] [ 6 ] * P [ 6 ] [ j ] ;
res + = KH [ i ] [ 22 ] * P [ 22 ] [ j ] ;
res + = KH [ i ] [ 23 ] * P [ 23 ] [ j ] ;
KHP [ i ] [ j ] = res ;
}
}
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
P [ i ] [ j ] = P [ i ] [ j ] - KHP [ i ] [ j ] ;
}
}
}
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// force the covariance matrix to be symmetrical and limit the variances to prevent ill-conditioning.
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ForceSymmetry ( ) ;
ConstrainVariances ( ) ;
}
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# if EK3_FEATURE_DRAG_FUSION
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/*
* Fuse X and Y body axis specific forces using explicit algebraic equations generated with SymPy .
* See AP_NavEKF3 / derivation / main . py for derivation
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* Output for change reference : AP_NavEKF3 / derivation / generated / acc_bf_generated . cpp
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*/
void NavEKF3_core : : FuseDragForces ( )
{
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// drag model parameters
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const ftype bcoef_x = frontend - > _ballisticCoef_x ;
const ftype bcoef_y = frontend - > _ballisticCoef_y ;
const ftype mcoef = frontend - > _momentumDragCoef . get ( ) ;
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const bool using_bcoef_x = bcoef_x > 1.0f ;
const bool using_bcoef_y = bcoef_y > 1.0f ;
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const bool using_mcoef = mcoef > 0.001f ;
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ZERO_FARRAY ( Kfusion ) ;
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Vector24 Hfusion ; // Observation Jacobians
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const ftype R_ACC = sq ( fmaxF ( frontend - > _dragObsNoise , 0.5f ) ) ;
const ftype density_ratio = sqrtF ( dal . get_EAS2TAS ( ) ) ;
const ftype rho = fmaxF ( 1.225f * density_ratio , 0.1f ) ; // air density
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// get latest estimated orientation
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const ftype & q0 = stateStruct . quat [ 0 ] ;
const ftype & q1 = stateStruct . quat [ 1 ] ;
const ftype & q2 = stateStruct . quat [ 2 ] ;
const ftype & q3 = stateStruct . quat [ 3 ] ;
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// get latest velocity in earth frame
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const ftype & vn = stateStruct . velocity . x ;
const ftype & ve = stateStruct . velocity . y ;
const ftype & vd = stateStruct . velocity . z ;
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// get latest wind velocity in earth frame
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const ftype & vwn = stateStruct . wind_vel . x ;
const ftype & vwe = stateStruct . wind_vel . y ;
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// predicted specific forces
// calculate relative wind velocity in earth frame and rotate into body frame
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const Vector3F rel_wind_earth ( vn - vwn , ve - vwe , vd ) ;
const Vector3F rel_wind_body = prevTnb * rel_wind_earth ;
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// perform sequential fusion of XY specific forces
for ( uint8_t axis_index = 0 ; axis_index < 2 ; axis_index + + ) {
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// correct accel data for bias
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const ftype mea_acc = dragSampleDelayed . accelXY [ axis_index ] - stateStruct . accel_bias [ axis_index ] / dtEkfAvg ;
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// Acceleration in m/s/s predicted using vehicle and wind velocity estimates
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// Initialised to measured value and updated later using available drag model
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ftype predAccel = mea_acc ;
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// predicted sign of drag force
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const ftype dragForceSign = is_positive ( rel_wind_body [ axis_index ] ) ? - 1.0f : 1.0f ;
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if ( axis_index = = 0 ) {
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// drag can be modelled as an arbitrary combination of bluff body drag that proportional to
// speed squared, and rotor momentum drag that is proportional to speed.
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ftype Kacc ; // Derivative of specific force wrt airspeed
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if ( using_mcoef & & using_bcoef_x ) {
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// mixed bluff body and propeller momentum drag
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const ftype airSpd = ( bcoef_x / rho ) * ( - mcoef + sqrtF ( sq ( mcoef ) + 2.0f * ( rho / bcoef_x ) * fabsF ( mea_acc ) ) ) ;
Kacc = fmaxF ( 1e-1 f , ( rho / bcoef_x ) * airSpd + mcoef * density_ratio ) ;
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predAccel = ( 0.5f / bcoef_x ) * rho * sq ( rel_wind_body [ 0 ] ) * dragForceSign - rel_wind_body [ 0 ] * mcoef * density_ratio ;
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} else if ( using_mcoef ) {
// propeller momentum drag only
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Kacc = fmaxF ( 1e-1 f , mcoef * density_ratio ) ;
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predAccel = - rel_wind_body [ 0 ] * mcoef * density_ratio ;
} else if ( using_bcoef_x ) {
// bluff body drag only
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const ftype airSpd = sqrtF ( ( 2.0f * bcoef_x * fabsF ( mea_acc ) ) / rho ) ;
Kacc = fmaxF ( 1e-1 f , ( rho / bcoef_x ) * airSpd ) ;
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predAccel = ( 0.5f / bcoef_x ) * rho * sq ( rel_wind_body [ 0 ] ) * dragForceSign ;
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} else {
// skip this axis
continue ;
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}
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// intermediate variables
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const ftype HK0 = vn - vwn ;
const ftype HK1 = ve - vwe ;
const ftype HK2 = HK0 * q0 + HK1 * q3 - q2 * vd ;
const ftype HK3 = 2 * Kacc ;
const ftype HK4 = HK0 * q1 + HK1 * q2 + q3 * vd ;
const ftype HK5 = HK0 * q2 - HK1 * q1 + q0 * vd ;
const ftype HK6 = - HK0 * q3 + HK1 * q0 + q1 * vd ;
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const ftype HK7 = sq ( q0 ) + sq ( q1 ) - sq ( q2 ) - sq ( q3 ) ;
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const ftype HK8 = HK7 * Kacc ;
const ftype HK9 = q0 * q3 + q1 * q2 ;
const ftype HK10 = HK3 * HK9 ;
const ftype HK11 = q0 * q2 - q1 * q3 ;
const ftype HK12 = 2 * HK9 ;
const ftype HK13 = 2 * HK11 ;
const ftype HK14 = 2 * HK4 ;
const ftype HK15 = 2 * HK2 ;
const ftype HK16 = 2 * HK5 ;
const ftype HK17 = 2 * HK6 ;
const ftype HK18 = - HK12 * P [ 0 ] [ 23 ] + HK12 * P [ 0 ] [ 5 ] - HK13 * P [ 0 ] [ 6 ] + HK14 * P [ 0 ] [ 1 ] + HK15 * P [ 0 ] [ 0 ] - HK16 * P [ 0 ] [ 2 ] + HK17 * P [ 0 ] [ 3 ] - HK7 * P [ 0 ] [ 22 ] + HK7 * P [ 0 ] [ 4 ] ;
const ftype HK19 = HK12 * P [ 5 ] [ 23 ] ;
const ftype HK20 = - HK12 * P [ 23 ] [ 23 ] - HK13 * P [ 6 ] [ 23 ] + HK14 * P [ 1 ] [ 23 ] + HK15 * P [ 0 ] [ 23 ] - HK16 * P [ 2 ] [ 23 ] + HK17 * P [ 3 ] [ 23 ] + HK19 - HK7 * P [ 22 ] [ 23 ] + HK7 * P [ 4 ] [ 23 ] ;
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const ftype HK21 = sq ( Kacc ) ;
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const ftype HK22 = HK12 * HK21 ;
const ftype HK23 = HK12 * P [ 5 ] [ 5 ] - HK13 * P [ 5 ] [ 6 ] + HK14 * P [ 1 ] [ 5 ] + HK15 * P [ 0 ] [ 5 ] - HK16 * P [ 2 ] [ 5 ] + HK17 * P [ 3 ] [ 5 ] - HK19 + HK7 * P [ 4 ] [ 5 ] - HK7 * P [ 5 ] [ 22 ] ;
const ftype HK24 = HK12 * P [ 5 ] [ 6 ] - HK12 * P [ 6 ] [ 23 ] - HK13 * P [ 6 ] [ 6 ] + HK14 * P [ 1 ] [ 6 ] + HK15 * P [ 0 ] [ 6 ] - HK16 * P [ 2 ] [ 6 ] + HK17 * P [ 3 ] [ 6 ] + HK7 * P [ 4 ] [ 6 ] - HK7 * P [ 6 ] [ 22 ] ;
const ftype HK25 = HK7 * P [ 4 ] [ 22 ] ;
const ftype HK26 = - HK12 * P [ 4 ] [ 23 ] + HK12 * P [ 4 ] [ 5 ] - HK13 * P [ 4 ] [ 6 ] + HK14 * P [ 1 ] [ 4 ] + HK15 * P [ 0 ] [ 4 ] - HK16 * P [ 2 ] [ 4 ] + HK17 * P [ 3 ] [ 4 ] - HK25 + HK7 * P [ 4 ] [ 4 ] ;
const ftype HK27 = HK21 * HK7 ;
const ftype HK28 = - HK12 * P [ 22 ] [ 23 ] + HK12 * P [ 5 ] [ 22 ] - HK13 * P [ 6 ] [ 22 ] + HK14 * P [ 1 ] [ 22 ] + HK15 * P [ 0 ] [ 22 ] - HK16 * P [ 2 ] [ 22 ] + HK17 * P [ 3 ] [ 22 ] + HK25 - HK7 * P [ 22 ] [ 22 ] ;
const ftype HK29 = - HK12 * P [ 1 ] [ 23 ] + HK12 * P [ 1 ] [ 5 ] - HK13 * P [ 1 ] [ 6 ] + HK14 * P [ 1 ] [ 1 ] + HK15 * P [ 0 ] [ 1 ] - HK16 * P [ 1 ] [ 2 ] + HK17 * P [ 1 ] [ 3 ] - HK7 * P [ 1 ] [ 22 ] + HK7 * P [ 1 ] [ 4 ] ;
const ftype HK30 = - HK12 * P [ 2 ] [ 23 ] + HK12 * P [ 2 ] [ 5 ] - HK13 * P [ 2 ] [ 6 ] + HK14 * P [ 1 ] [ 2 ] + HK15 * P [ 0 ] [ 2 ] - HK16 * P [ 2 ] [ 2 ] + HK17 * P [ 2 ] [ 3 ] - HK7 * P [ 2 ] [ 22 ] + HK7 * P [ 2 ] [ 4 ] ;
const ftype HK31 = - HK12 * P [ 3 ] [ 23 ] + HK12 * P [ 3 ] [ 5 ] - HK13 * P [ 3 ] [ 6 ] + HK14 * P [ 1 ] [ 3 ] + HK15 * P [ 0 ] [ 3 ] - HK16 * P [ 2 ] [ 3 ] + HK17 * P [ 3 ] [ 3 ] - HK7 * P [ 3 ] [ 22 ] + HK7 * P [ 3 ] [ 4 ] ;
// const ftype HK32 = Kacc/(-HK13*HK21*HK24 + HK14*HK21*HK29 + HK15*HK18*HK21 - HK16*HK21*HK30 + HK17*HK21*HK31 - HK20*HK22 + HK22*HK23 + HK26*HK27 - HK27*HK28 + R_ACC);
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// calculate innovation variance and exit if badly conditioned
innovDragVar . x = ( - HK13 * HK21 * HK24 + HK14 * HK21 * HK29 + HK15 * HK18 * HK21 - HK16 * HK21 * HK30 + HK17 * HK21 * HK31 - HK20 * HK22 + HK22 * HK23 + HK26 * HK27 - HK27 * HK28 + R_ACC ) ;
if ( innovDragVar . x < R_ACC ) {
return ;
}
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const ftype HK32 = Kacc / innovDragVar . x ;
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// Observation Jacobians
Hfusion [ 0 ] = - HK2 * HK3 ;
Hfusion [ 1 ] = - HK3 * HK4 ;
Hfusion [ 2 ] = HK3 * HK5 ;
Hfusion [ 3 ] = - HK3 * HK6 ;
Hfusion [ 4 ] = - HK8 ;
Hfusion [ 5 ] = - HK10 ;
Hfusion [ 6 ] = HK11 * HK3 ;
Hfusion [ 22 ] = HK8 ;
Hfusion [ 23 ] = HK10 ;
// Kalman gains
// Don't allow modification of any states other than wind velocity - we only need a wind estimate.
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// See AP_NavEKF3/derivation/generated/acc_bf_generated.cpp for un-implemented Kalman gain equations.
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Kfusion [ 22 ] = - HK28 * HK32 ;
Kfusion [ 23 ] = - HK20 * HK32 ;
} else if ( axis_index = = 1 ) {
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// drag can be modelled as an arbitrary combination of bluff body drag that proportional to
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// speed squared, and rotor momentum drag that is proportional to speed.
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ftype Kacc ; // Derivative of specific force wrt airspeed
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if ( using_mcoef & & using_bcoef_y ) {
// mixed bluff body and propeller momentum drag
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const ftype airSpd = ( bcoef_y / rho ) * ( - mcoef + sqrtF ( sq ( mcoef ) + 2.0f * ( rho / bcoef_y ) * fabsF ( mea_acc ) ) ) ;
Kacc = fmaxF ( 1e-1 f , ( rho / bcoef_y ) * airSpd + mcoef * density_ratio ) ;
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predAccel = ( 0.5f / bcoef_y ) * rho * sq ( rel_wind_body [ 1 ] ) * dragForceSign - rel_wind_body [ 1 ] * mcoef * density_ratio ;
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} else if ( using_mcoef ) {
// propeller momentum drag only
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Kacc = fmaxF ( 1e-1 f , mcoef * density_ratio ) ;
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predAccel = - rel_wind_body [ 1 ] * mcoef * density_ratio ;
} else if ( using_bcoef_y ) {
// bluff body drag only
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const ftype airSpd = sqrtF ( ( 2.0f * bcoef_y * fabsF ( mea_acc ) ) / rho ) ;
Kacc = fmaxF ( 1e-1 f , ( rho / bcoef_y ) * airSpd ) ;
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predAccel = ( 0.5f / bcoef_y ) * rho * sq ( rel_wind_body [ 1 ] ) * dragForceSign ;
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} else {
// nothing more to do
return ;
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}
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// intermediate variables
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const ftype HK0 = ve - vwe ;
const ftype HK1 = vn - vwn ;
const ftype HK2 = HK0 * q0 - HK1 * q3 + q1 * vd ;
const ftype HK3 = 2 * Kacc ;
const ftype HK4 = - HK0 * q1 + HK1 * q2 + q0 * vd ;
const ftype HK5 = HK0 * q2 + HK1 * q1 + q3 * vd ;
const ftype HK6 = HK0 * q3 + HK1 * q0 - q2 * vd ;
const ftype HK7 = q0 * q3 - q1 * q2 ;
const ftype HK8 = HK3 * HK7 ;
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const ftype HK9 = sq ( q0 ) - sq ( q1 ) + sq ( q2 ) - sq ( q3 ) ;
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const ftype HK10 = HK9 * Kacc ;
const ftype HK11 = q0 * q1 + q2 * q3 ;
const ftype HK12 = 2 * HK11 ;
const ftype HK13 = 2 * HK7 ;
const ftype HK14 = 2 * HK5 ;
const ftype HK15 = 2 * HK2 ;
const ftype HK16 = 2 * HK4 ;
const ftype HK17 = 2 * HK6 ;
const ftype HK18 = HK12 * P [ 0 ] [ 6 ] + HK13 * P [ 0 ] [ 22 ] - HK13 * P [ 0 ] [ 4 ] + HK14 * P [ 0 ] [ 2 ] + HK15 * P [ 0 ] [ 0 ] + HK16 * P [ 0 ] [ 1 ] - HK17 * P [ 0 ] [ 3 ] - HK9 * P [ 0 ] [ 23 ] + HK9 * P [ 0 ] [ 5 ] ;
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const ftype HK19 = sq ( Kacc ) ;
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const ftype HK20 = HK12 * P [ 6 ] [ 6 ] - HK13 * P [ 4 ] [ 6 ] + HK13 * P [ 6 ] [ 22 ] + HK14 * P [ 2 ] [ 6 ] + HK15 * P [ 0 ] [ 6 ] + HK16 * P [ 1 ] [ 6 ] - HK17 * P [ 3 ] [ 6 ] + HK9 * P [ 5 ] [ 6 ] - HK9 * P [ 6 ] [ 23 ] ;
const ftype HK21 = HK13 * P [ 4 ] [ 22 ] ;
const ftype HK22 = HK12 * P [ 6 ] [ 22 ] + HK13 * P [ 22 ] [ 22 ] + HK14 * P [ 2 ] [ 22 ] + HK15 * P [ 0 ] [ 22 ] + HK16 * P [ 1 ] [ 22 ] - HK17 * P [ 3 ] [ 22 ] - HK21 - HK9 * P [ 22 ] [ 23 ] + HK9 * P [ 5 ] [ 22 ] ;
const ftype HK23 = HK13 * HK19 ;
const ftype HK24 = HK12 * P [ 4 ] [ 6 ] - HK13 * P [ 4 ] [ 4 ] + HK14 * P [ 2 ] [ 4 ] + HK15 * P [ 0 ] [ 4 ] + HK16 * P [ 1 ] [ 4 ] - HK17 * P [ 3 ] [ 4 ] + HK21 - HK9 * P [ 4 ] [ 23 ] + HK9 * P [ 4 ] [ 5 ] ;
const ftype HK25 = HK9 * P [ 5 ] [ 23 ] ;
const ftype HK26 = HK12 * P [ 5 ] [ 6 ] - HK13 * P [ 4 ] [ 5 ] + HK13 * P [ 5 ] [ 22 ] + HK14 * P [ 2 ] [ 5 ] + HK15 * P [ 0 ] [ 5 ] + HK16 * P [ 1 ] [ 5 ] - HK17 * P [ 3 ] [ 5 ] - HK25 + HK9 * P [ 5 ] [ 5 ] ;
const ftype HK27 = HK19 * HK9 ;
const ftype HK28 = HK12 * P [ 6 ] [ 23 ] + HK13 * P [ 22 ] [ 23 ] - HK13 * P [ 4 ] [ 23 ] + HK14 * P [ 2 ] [ 23 ] + HK15 * P [ 0 ] [ 23 ] + HK16 * P [ 1 ] [ 23 ] - HK17 * P [ 3 ] [ 23 ] + HK25 - HK9 * P [ 23 ] [ 23 ] ;
const ftype HK29 = HK12 * P [ 2 ] [ 6 ] + HK13 * P [ 2 ] [ 22 ] - HK13 * P [ 2 ] [ 4 ] + HK14 * P [ 2 ] [ 2 ] + HK15 * P [ 0 ] [ 2 ] + HK16 * P [ 1 ] [ 2 ] - HK17 * P [ 2 ] [ 3 ] - HK9 * P [ 2 ] [ 23 ] + HK9 * P [ 2 ] [ 5 ] ;
const ftype HK30 = HK12 * P [ 1 ] [ 6 ] + HK13 * P [ 1 ] [ 22 ] - HK13 * P [ 1 ] [ 4 ] + HK14 * P [ 1 ] [ 2 ] + HK15 * P [ 0 ] [ 1 ] + HK16 * P [ 1 ] [ 1 ] - HK17 * P [ 1 ] [ 3 ] - HK9 * P [ 1 ] [ 23 ] + HK9 * P [ 1 ] [ 5 ] ;
const ftype HK31 = HK12 * P [ 3 ] [ 6 ] + HK13 * P [ 3 ] [ 22 ] - HK13 * P [ 3 ] [ 4 ] + HK14 * P [ 2 ] [ 3 ] + HK15 * P [ 0 ] [ 3 ] + HK16 * P [ 1 ] [ 3 ] - HK17 * P [ 3 ] [ 3 ] - HK9 * P [ 3 ] [ 23 ] + HK9 * P [ 3 ] [ 5 ] ;
// const ftype HK32 = Kaccy/(HK12*HK19*HK20 + HK14*HK19*HK29 + HK15*HK18*HK19 + HK16*HK19*HK30 - HK17*HK19*HK31 + HK22*HK23 - HK23*HK24 + HK26*HK27 - HK27*HK28 + R_ACC);
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innovDragVar . y = ( HK12 * HK19 * HK20 + HK14 * HK19 * HK29 + HK15 * HK18 * HK19 + HK16 * HK19 * HK30 - HK17 * HK19 * HK31 + HK22 * HK23 - HK23 * HK24 + HK26 * HK27 - HK27 * HK28 + R_ACC ) ;
if ( innovDragVar . y < R_ACC ) {
// calculation is badly conditioned
return ;
}
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const ftype HK32 = Kacc / innovDragVar . y ;
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// Observation Jacobians
Hfusion [ 0 ] = - HK2 * HK3 ;
Hfusion [ 1 ] = - HK3 * HK4 ;
Hfusion [ 2 ] = - HK3 * HK5 ;
Hfusion [ 3 ] = HK3 * HK6 ;
Hfusion [ 4 ] = HK8 ;
Hfusion [ 5 ] = - HK10 ;
Hfusion [ 6 ] = - HK11 * HK3 ;
Hfusion [ 22 ] = - HK8 ;
Hfusion [ 23 ] = HK10 ;
// Kalman gains
// Don't allow modification of any states other than wind velocity at this stage of development - we only need a wind estimate.
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// See AP_NavEKF3/derivation/generated/acc_bf_generated.cpp for un-implemented Kalman gain equations.
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Kfusion [ 22 ] = - HK22 * HK32 ;
Kfusion [ 23 ] = - HK28 * HK32 ;
}
innovDrag [ axis_index ] = predAccel - mea_acc ;
dragTestRatio [ axis_index ] = sq ( innovDrag [ axis_index ] ) / ( 25.0f * innovDragVar [ axis_index ] ) ;
// if the innovation consistency check fails then don't fuse the sample
if ( dragTestRatio [ axis_index ] > 1.0f ) {
return ;
}
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// correct the state vector
for ( uint8_t j = 0 ; j < = stateIndexLim ; j + + ) {
statesArray [ j ] = statesArray [ j ] - Kfusion [ j ] * innovDrag [ axis_index ] ;
}
stateStruct . quat . normalize ( ) ;
// correct the covariance P = (I - K*H)*P
// take advantage of the empty columns in KH to reduce the
// number of operations
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = 6 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * Hfusion [ j ] ;
}
for ( unsigned j = 7 ; j < = 21 ; j + + ) {
KH [ i ] [ j ] = 0.0f ;
}
for ( unsigned j = 22 ; j < = 23 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * Hfusion [ j ] ;
}
}
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
ftype res = 0 ;
res + = KH [ i ] [ 0 ] * P [ 0 ] [ j ] ;
res + = KH [ i ] [ 1 ] * P [ 1 ] [ j ] ;
res + = KH [ i ] [ 2 ] * P [ 2 ] [ j ] ;
res + = KH [ i ] [ 3 ] * P [ 3 ] [ j ] ;
res + = KH [ i ] [ 4 ] * P [ 4 ] [ j ] ;
res + = KH [ i ] [ 5 ] * P [ 5 ] [ j ] ;
res + = KH [ i ] [ 6 ] * P [ 6 ] [ j ] ;
res + = KH [ i ] [ 22 ] * P [ 22 ] [ j ] ;
res + = KH [ i ] [ 23 ] * P [ 23 ] [ j ] ;
KHP [ i ] [ j ] = res ;
}
}
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
P [ i ] [ j ] = P [ i ] [ j ] - KHP [ i ] [ j ] ;
}
}
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}
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// record time of successful fusion
lastDragPassTime_ms = imuSampleTime_ms ;
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}
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# endif // EK3_FEATURE_DRAG_FUSION
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/********************************************************
* MISC FUNCTIONS *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
