2015-10-05 23:30:07 -03:00
/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
# include <AP_HAL/AP_HAL.h>
# if HAL_CPU_CLASS >= HAL_CPU_CLASS_150
# include "AP_NavEKF2.h"
# include "AP_NavEKF2_core.h"
# include <AP_AHRS/AP_AHRS.h>
# include <AP_Vehicle/AP_Vehicle.h>
# include <stdio.h>
extern const AP_HAL : : HAL & hal ;
/********************************************************
* RESET FUNCTIONS *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// Control reset of yaw and magnetic field states
void NavEKF2_core : : controlMagYawReset ( )
{
2015-10-30 08:05:31 -03:00
// Use a quaternion division to calcualte the delta quaternion between the rotation at the current and last time
Quaternion deltaQuat = stateStruct . quat / prevQuatMagReset ;
prevQuatMagReset = stateStruct . quat ;
// convert the quaternion to a rotation vector and find its length
Vector3f deltaRotVec ;
deltaQuat . to_axis_angle ( deltaRotVec ) ;
float deltaRot = deltaRotVec . length ( ) ;
2015-10-05 23:30:07 -03:00
// Monitor the gain in height and reset the magnetic field states and heading when initial altitude has been gained
// This is done to prevent magnetic field distoration from steel roofs and adjacent structures causing bad earth field and initial yaw values
2015-10-30 08:05:31 -03:00
// Delay if rotated too far since the last check as rapid rotations will produce errors in the magnetic field states
if ( inFlight & & ! firstMagYawInit & & ( stateStruct . position . z - posDownAtTakeoff ) < - 5.0f & & deltaRot < 0.1745f ) {
2015-10-28 06:06:40 -03:00
firstMagYawInit = true ;
// reset the timer used to prevent magnetometer fusion from affecting attitude until initial field learning is complete
magFuseTiltInhibit_ms = imuSampleTime_ms ;
// Update the yaw angle and earth field states using the magnetic field measurements
Quaternion tempQuat ;
Vector3f eulerAngles ;
stateStruct . quat . to_euler ( eulerAngles . x , eulerAngles . y , eulerAngles . z ) ;
tempQuat = stateStruct . quat ;
stateStruct . quat = calcQuatAndFieldStates ( eulerAngles . x , eulerAngles . y ) ;
// calculate the change in the quaternion state and apply it to the ouput history buffer
tempQuat = stateStruct . quat / tempQuat ;
StoreQuatRotate ( tempQuat ) ;
}
2015-10-05 23:30:07 -03:00
// perform a yaw alignment check against GPS if exiting on-ground mode for fly forward type vehicle (plane)
// this is done to protect against unrecoverable heading alignment errors due to compass faults
if ( ! onGround & & prevOnGround & & assume_zero_sideslip ( ) ) {
alignYawGPS ( ) ;
}
2015-10-22 20:15:23 -03:00
// inhibit the 3-axis mag fusion from modifying the tilt states for the first few seconds after a mag field reset
// to allow the mag states to converge and prevent disturbances in roll and pitch.
if ( imuSampleTime_ms - magFuseTiltInhibit_ms < 5000 ) {
magFuseTiltInhibit = true ;
} else {
magFuseTiltInhibit = false ;
}
2015-10-05 23:30:07 -03:00
}
// this function is used to do a forced alignment of the yaw angle to align with the horizontal velocity
// vector from GPS. It is used to align the yaw angle after launch or takeoff.
void NavEKF2_core : : alignYawGPS ( )
{
if ( ( sq ( gpsDataDelayed . vel . x ) + sq ( gpsDataDelayed . vel . y ) ) > 25.0f ) {
float roll ;
float pitch ;
float oldYaw ;
float newYaw ;
float yawErr ;
// get quaternion from existing filter states and calculate roll, pitch and yaw angles
stateStruct . quat . to_euler ( roll , pitch , oldYaw ) ;
// calculate course yaw angle
oldYaw = atan2f ( stateStruct . velocity . y , stateStruct . velocity . x ) ;
// calculate yaw angle from GPS velocity
newYaw = atan2f ( gpsDataNew . vel . y , gpsDataNew . vel . x ) ;
// estimate the yaw error
yawErr = wrap_PI ( newYaw - oldYaw ) ;
// If the inertial course angle disagrees with the GPS by more than 45 degrees, we declare the compass as bad
badMag = ( fabsf ( yawErr ) > 0.7854f ) ;
// correct yaw angle using GPS ground course compass failed or if not previously aligned
if ( badMag | | ! yawAligned ) {
// correct the yaw angle
newYaw = oldYaw + yawErr ;
// calculate new filter quaternion states from Euler angles
stateStruct . quat . from_euler ( roll , pitch , newYaw ) ;
// the yaw angle is now aligned so update its status
yawAligned = true ;
// reset the position and velocity states
ResetPosition ( ) ;
ResetVelocity ( ) ;
// reset the covariance for the quaternion, velocity and position states
// zero the matrix entries
zeroRows ( P , 0 , 9 ) ;
zeroCols ( P , 0 , 9 ) ;
// velocities - we could have a big error coming out of constant position mode due to GPS lag
P [ 3 ] [ 3 ] = 400.0f ;
P [ 4 ] [ 4 ] = P [ 3 ] [ 3 ] ;
P [ 5 ] [ 5 ] = sq ( 0.7f ) ;
// positions - we could have a big error coming out of constant position mode due to GPS lag
P [ 6 ] [ 6 ] = 400.0f ;
P [ 7 ] [ 7 ] = P [ 6 ] [ 6 ] ;
P [ 8 ] [ 8 ] = sq ( 5.0f ) ;
}
// Update magnetic field states if the magnetometer is bad
if ( badMag ) {
Vector3f eulerAngles ;
getEulerAngles ( eulerAngles ) ;
calcQuatAndFieldStates ( eulerAngles . x , eulerAngles . y ) ;
}
}
}
/********************************************************
* FUSE MEASURED_DATA *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// select fusion of magnetometer data
void NavEKF2_core : : SelectMagFusion ( )
{
// start performance timer
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_FuseMagnetometer ) ;
2015-10-05 23:30:07 -03:00
2015-10-18 19:34:11 -03:00
// clear the flag that lets other processes know that the expensive magnetometer fusion operation has been perfomred on that time step
// used for load levelling
magFusePerformed = false ;
2015-10-05 23:30:07 -03:00
// check for and read new magnetometer measurements
readMagData ( ) ;
// If we are using the compass and the magnetometer has been unhealthy for too long we declare a timeout
if ( magHealth ) {
magTimeout = false ;
lastHealthyMagTime_ms = imuSampleTime_ms ;
} else if ( ( imuSampleTime_ms - lastHealthyMagTime_ms ) > frontend . magFailTimeLimit_ms & & use_compass ( ) ) {
magTimeout = true ;
}
2015-10-28 06:06:40 -03:00
// check for availability of magnetometer data to fuse
bool newMagDataAvailable = RecallMag ( ) ;
if ( newMagDataAvailable ) {
// Control reset of yaw and magnetic field states
controlMagYawReset ( ) ;
}
2015-10-05 23:30:07 -03:00
// determine if conditions are right to start a new fusion cycle
// wait until the EKF time horizon catches up with the measurement
2015-10-28 06:06:40 -03:00
bool dataReady = ( newMagDataAvailable & & statesInitialised & & use_compass ( ) & & yawAlignComplete ) ;
2015-10-05 23:30:07 -03:00
if ( dataReady ) {
// ensure that the covariance prediction is up to date before fusing data
if ( ! covPredStep ) CovariancePrediction ( ) ;
// If we haven't performed the first airborne magnetic field update or have inhibited magnetic field learning, then we use the simple method of declination to maintain heading
if ( inhibitMagStates ) {
fuseCompass ( ) ;
2015-10-28 22:36:53 -03:00
// zero the test ratio output from the inactive 3-axis magneteometer fusion
magTestRatio . zero ( ) ;
2015-10-05 23:30:07 -03:00
} else {
2015-10-18 07:16:55 -03:00
// if we are not doing aiding with earth relative observations (eg GPS) then the declination is
// maintained by fusing declination as a synthesised observation
2015-10-23 09:44:43 -03:00
if ( PV_AidingMode ! = AID_ABSOLUTE | | ( imuSampleTime_ms - lastPosPassTime_ms ) > 4000 ) {
2015-10-18 07:16:55 -03:00
FuseDeclination ( ) ;
}
2015-10-05 23:30:07 -03:00
// fuse the three magnetometer componenents sequentially
2015-10-19 18:32:07 -03:00
for ( mag_state . obsIndex = 0 ; mag_state . obsIndex < = 2 ; mag_state . obsIndex + + ) {
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 0 ] ) ;
2015-10-19 18:32:07 -03:00
FuseMagnetometer ( ) ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 0 ] ) ;
2015-10-19 18:32:07 -03:00
}
2015-10-28 22:36:53 -03:00
// zero the test ratio output from the inactive simple magnetometer yaw fusion
yawTestRatio = 0.0f ;
2015-10-05 23:30:07 -03:00
}
}
// stop performance timer
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_FuseMagnetometer ) ;
2015-10-05 23:30:07 -03:00
}
2015-10-17 20:32:11 -03:00
/*
* Fuse magnetometer 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 :
* https : //github.com/priseborough/InertialNav/blob/master/derivations/RotationVectorAttitudeParameterisation/GenerateNavFilterEquations.m
*/
2015-10-05 23:30:07 -03:00
void NavEKF2_core : : FuseMagnetometer ( )
{
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 1 ] ) ;
2015-10-19 18:32:07 -03:00
2015-10-05 23:30:07 -03:00
// declarations
ftype & q0 = mag_state . q0 ;
ftype & q1 = mag_state . q1 ;
ftype & q2 = mag_state . q2 ;
ftype & q3 = mag_state . q3 ;
ftype & magN = mag_state . magN ;
ftype & magE = mag_state . magE ;
ftype & magD = mag_state . magD ;
ftype & magXbias = mag_state . magXbias ;
ftype & magYbias = mag_state . magYbias ;
ftype & magZbias = mag_state . magZbias ;
uint8_t & obsIndex = mag_state . obsIndex ;
Matrix3f & DCM = mag_state . DCM ;
Vector3f & MagPred = mag_state . MagPred ;
ftype & R_MAG = mag_state . R_MAG ;
ftype * SH_MAG = & mag_state . SH_MAG [ 0 ] ;
Vector24 H_MAG ;
Vector6 SK_MX ;
Vector6 SK_MY ;
Vector6 SK_MZ ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 1 ] ) ;
2015-10-19 18:32:07 -03:00
2015-10-05 23:30:07 -03:00
// perform sequential fusion of magnetometer measurements.
// this assumes that the errors in the different components are
// uncorrelated which is not true, however in the absence of covariance
// data fit is the only assumption we can make
// so we might as well take advantage of the computational efficiencies
// associated with sequential fusion
// calculate observation jacobians and Kalman gains
if ( obsIndex = = 0 )
{
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 2 ] ) ;
2015-10-05 23:30:07 -03:00
// copy required states to local variable names
q0 = stateStruct . quat [ 0 ] ;
q1 = stateStruct . quat [ 1 ] ;
q2 = stateStruct . quat [ 2 ] ;
q3 = stateStruct . quat [ 3 ] ;
magN = stateStruct . earth_magfield [ 0 ] ;
magE = stateStruct . earth_magfield [ 1 ] ;
magD = stateStruct . earth_magfield [ 2 ] ;
magXbias = stateStruct . body_magfield [ 0 ] ;
magYbias = stateStruct . body_magfield [ 1 ] ;
magZbias = stateStruct . body_magfield [ 2 ] ;
// rotate predicted earth components into body axes and calculate
// predicted measurements
DCM [ 0 ] [ 0 ] = q0 * q0 + q1 * q1 - q2 * q2 - q3 * q3 ;
2015-10-19 05:29:11 -03:00
DCM [ 0 ] [ 1 ] = 2.0f * ( q1 * q2 + q0 * q3 ) ;
DCM [ 0 ] [ 2 ] = 2.0f * ( q1 * q3 - q0 * q2 ) ;
DCM [ 1 ] [ 0 ] = 2.0f * ( q1 * q2 - q0 * q3 ) ;
2015-10-05 23:30:07 -03:00
DCM [ 1 ] [ 1 ] = q0 * q0 - q1 * q1 + q2 * q2 - q3 * q3 ;
2015-10-19 05:29:11 -03:00
DCM [ 1 ] [ 2 ] = 2.0f * ( q2 * q3 + q0 * q1 ) ;
DCM [ 2 ] [ 0 ] = 2.0f * ( q1 * q3 + q0 * q2 ) ;
DCM [ 2 ] [ 1 ] = 2.0f * ( q2 * q3 - q0 * q1 ) ;
2015-10-05 23:30:07 -03:00
DCM [ 2 ] [ 2 ] = q0 * q0 - q1 * q1 - q2 * q2 + q3 * q3 ;
MagPred [ 0 ] = DCM [ 0 ] [ 0 ] * magN + DCM [ 0 ] [ 1 ] * magE + DCM [ 0 ] [ 2 ] * magD + magXbias ;
MagPred [ 1 ] = DCM [ 1 ] [ 0 ] * magN + DCM [ 1 ] [ 1 ] * magE + DCM [ 1 ] [ 2 ] * magD + magYbias ;
MagPred [ 2 ] = DCM [ 2 ] [ 0 ] * magN + DCM [ 2 ] [ 1 ] * magE + DCM [ 2 ] [ 2 ] * magD + magZbias ;
2015-10-24 06:10:20 -03:00
// scale magnetometer observation error with total angular rate to allow for timing errors
2015-10-05 23:30:07 -03:00
R_MAG = sq ( constrain_float ( frontend . _magNoise , 0.01f , 0.5f ) ) + sq ( frontend . magVarRateScale * imuDataDelayed . delAng . length ( ) / dtIMUavg ) ;
// calculate observation jacobians
SH_MAG [ 0 ] = sq ( q0 ) - sq ( q1 ) + sq ( q2 ) - sq ( q3 ) ;
SH_MAG [ 1 ] = sq ( q0 ) + sq ( q1 ) - sq ( q2 ) - sq ( q3 ) ;
SH_MAG [ 2 ] = sq ( q0 ) - sq ( q1 ) - sq ( q2 ) + sq ( q3 ) ;
2015-10-19 05:29:11 -03:00
SH_MAG [ 3 ] = 2.0f * q0 * q1 + 2.0f * q2 * q3 ;
SH_MAG [ 4 ] = 2.0f * q0 * q3 + 2.0f * q1 * q2 ;
SH_MAG [ 5 ] = 2.0f * q0 * q2 + 2.0f * q1 * q3 ;
SH_MAG [ 6 ] = magE * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) ;
SH_MAG [ 7 ] = 2.0f * q1 * q3 - 2.0f * q0 * q2 ;
SH_MAG [ 8 ] = 2.0f * q0 * q3 ;
2015-10-05 23:30:07 -03:00
for ( uint8_t i = 0 ; i < = stateIndexLim ; i + + ) H_MAG [ i ] = 0.0f ;
H_MAG [ 1 ] = SH_MAG [ 6 ] - magD * SH_MAG [ 2 ] - magN * SH_MAG [ 5 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 2 ] = magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ;
2015-10-05 23:30:07 -03:00
H_MAG [ 16 ] = SH_MAG [ 1 ] ;
H_MAG [ 17 ] = SH_MAG [ 4 ] ;
H_MAG [ 18 ] = SH_MAG [ 7 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 19 ] = 1.0f ;
2015-10-05 23:30:07 -03:00
// calculate Kalman gain
2015-10-19 05:29:11 -03:00
varInnovMag [ 0 ] = ( P [ 19 ] [ 19 ] + R_MAG - P [ 1 ] [ 19 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 16 ] [ 19 ] * SH_MAG [ 1 ] + P [ 17 ] [ 19 ] * SH_MAG [ 4 ] + P [ 18 ] [ 19 ] * SH_MAG [ 7 ] + P [ 2 ] [ 19 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) - ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) * ( P [ 19 ] [ 1 ] - P [ 1 ] [ 1 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 16 ] [ 1 ] * SH_MAG [ 1 ] + P [ 17 ] [ 1 ] * SH_MAG [ 4 ] + P [ 18 ] [ 1 ] * SH_MAG [ 7 ] + P [ 2 ] [ 1 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) ) + SH_MAG [ 1 ] * ( P [ 19 ] [ 16 ] - P [ 1 ] [ 16 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 16 ] [ 16 ] * SH_MAG [ 1 ] + P [ 17 ] [ 16 ] * SH_MAG [ 4 ] + P [ 18 ] [ 16 ] * SH_MAG [ 7 ] + P [ 2 ] [ 16 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) ) + SH_MAG [ 4 ] * ( P [ 19 ] [ 17 ] - P [ 1 ] [ 17 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 16 ] [ 17 ] * SH_MAG [ 1 ] + P [ 17 ] [ 17 ] * SH_MAG [ 4 ] + P [ 18 ] [ 17 ] * SH_MAG [ 7 ] + P [ 2 ] [ 17 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) ) + SH_MAG [ 7 ] * ( P [ 19 ] [ 18 ] - P [ 1 ] [ 18 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 16 ] [ 18 ] * SH_MAG [ 1 ] + P [ 17 ] [ 18 ] * SH_MAG [ 4 ] + P [ 18 ] [ 18 ] * SH_MAG [ 7 ] + P [ 2 ] [ 18 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) ) + ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) * ( P [ 19 ] [ 2 ] - P [ 1 ] [ 2 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 16 ] [ 2 ] * SH_MAG [ 1 ] + P [ 17 ] [ 2 ] * SH_MAG [ 4 ] + P [ 18 ] [ 2 ] * SH_MAG [ 7 ] + P [ 2 ] [ 2 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) ) ) ;
2015-10-05 23:30:07 -03:00
if ( varInnovMag [ 0 ] > = R_MAG ) {
SK_MX [ 0 ] = 1.0f / varInnovMag [ 0 ] ;
faultStatus . bad_xmag = 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 ( ) ;
obsIndex = 1 ;
faultStatus . bad_xmag = true ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 2 ] ) ;
2015-10-05 23:30:07 -03:00
return ;
}
2015-10-19 05:29:11 -03:00
SK_MX [ 1 ] = magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ;
2015-10-05 23:30:07 -03:00
SK_MX [ 2 ] = magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ;
SK_MX [ 3 ] = SH_MAG [ 7 ] ;
Kfusion [ 0 ] = SK_MX [ 0 ] * ( P [ 0 ] [ 19 ] + P [ 0 ] [ 16 ] * SH_MAG [ 1 ] + P [ 0 ] [ 17 ] * SH_MAG [ 4 ] - P [ 0 ] [ 1 ] * SK_MX [ 2 ] + P [ 0 ] [ 2 ] * SK_MX [ 1 ] + P [ 0 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 1 ] = SK_MX [ 0 ] * ( P [ 1 ] [ 19 ] + P [ 1 ] [ 16 ] * SH_MAG [ 1 ] + P [ 1 ] [ 17 ] * SH_MAG [ 4 ] - P [ 1 ] [ 1 ] * SK_MX [ 2 ] + P [ 1 ] [ 2 ] * SK_MX [ 1 ] + P [ 1 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 2 ] = SK_MX [ 0 ] * ( P [ 2 ] [ 19 ] + P [ 2 ] [ 16 ] * SH_MAG [ 1 ] + P [ 2 ] [ 17 ] * SH_MAG [ 4 ] - P [ 2 ] [ 1 ] * SK_MX [ 2 ] + P [ 2 ] [ 2 ] * SK_MX [ 1 ] + P [ 2 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 3 ] = SK_MX [ 0 ] * ( P [ 3 ] [ 19 ] + P [ 3 ] [ 16 ] * SH_MAG [ 1 ] + P [ 3 ] [ 17 ] * SH_MAG [ 4 ] - P [ 3 ] [ 1 ] * SK_MX [ 2 ] + P [ 3 ] [ 2 ] * SK_MX [ 1 ] + P [ 3 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 4 ] = SK_MX [ 0 ] * ( P [ 4 ] [ 19 ] + P [ 4 ] [ 16 ] * SH_MAG [ 1 ] + P [ 4 ] [ 17 ] * SH_MAG [ 4 ] - P [ 4 ] [ 1 ] * SK_MX [ 2 ] + P [ 4 ] [ 2 ] * SK_MX [ 1 ] + P [ 4 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 5 ] = SK_MX [ 0 ] * ( P [ 5 ] [ 19 ] + P [ 5 ] [ 16 ] * SH_MAG [ 1 ] + P [ 5 ] [ 17 ] * SH_MAG [ 4 ] - P [ 5 ] [ 1 ] * SK_MX [ 2 ] + P [ 5 ] [ 2 ] * SK_MX [ 1 ] + P [ 5 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 6 ] = SK_MX [ 0 ] * ( P [ 6 ] [ 19 ] + P [ 6 ] [ 16 ] * SH_MAG [ 1 ] + P [ 6 ] [ 17 ] * SH_MAG [ 4 ] - P [ 6 ] [ 1 ] * SK_MX [ 2 ] + P [ 6 ] [ 2 ] * SK_MX [ 1 ] + P [ 6 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 7 ] = SK_MX [ 0 ] * ( P [ 7 ] [ 19 ] + P [ 7 ] [ 16 ] * SH_MAG [ 1 ] + P [ 7 ] [ 17 ] * SH_MAG [ 4 ] - P [ 7 ] [ 1 ] * SK_MX [ 2 ] + P [ 7 ] [ 2 ] * SK_MX [ 1 ] + P [ 7 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 8 ] = SK_MX [ 0 ] * ( P [ 8 ] [ 19 ] + P [ 8 ] [ 16 ] * SH_MAG [ 1 ] + P [ 8 ] [ 17 ] * SH_MAG [ 4 ] - P [ 8 ] [ 1 ] * SK_MX [ 2 ] + P [ 8 ] [ 2 ] * SK_MX [ 1 ] + P [ 8 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 9 ] = SK_MX [ 0 ] * ( P [ 9 ] [ 19 ] + P [ 9 ] [ 16 ] * SH_MAG [ 1 ] + P [ 9 ] [ 17 ] * SH_MAG [ 4 ] - P [ 9 ] [ 1 ] * SK_MX [ 2 ] + P [ 9 ] [ 2 ] * SK_MX [ 1 ] + P [ 9 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 10 ] = SK_MX [ 0 ] * ( P [ 10 ] [ 19 ] + P [ 10 ] [ 16 ] * SH_MAG [ 1 ] + P [ 10 ] [ 17 ] * SH_MAG [ 4 ] - P [ 10 ] [ 1 ] * SK_MX [ 2 ] + P [ 10 ] [ 2 ] * SK_MX [ 1 ] + P [ 10 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 11 ] = SK_MX [ 0 ] * ( P [ 11 ] [ 19 ] + P [ 11 ] [ 16 ] * SH_MAG [ 1 ] + P [ 11 ] [ 17 ] * SH_MAG [ 4 ] - P [ 11 ] [ 1 ] * SK_MX [ 2 ] + P [ 11 ] [ 2 ] * SK_MX [ 1 ] + P [ 11 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 12 ] = SK_MX [ 0 ] * ( P [ 12 ] [ 19 ] + P [ 12 ] [ 16 ] * SH_MAG [ 1 ] + P [ 12 ] [ 17 ] * SH_MAG [ 4 ] - P [ 12 ] [ 1 ] * SK_MX [ 2 ] + P [ 12 ] [ 2 ] * SK_MX [ 1 ] + P [ 12 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 13 ] = SK_MX [ 0 ] * ( P [ 13 ] [ 19 ] + P [ 13 ] [ 16 ] * SH_MAG [ 1 ] + P [ 13 ] [ 17 ] * SH_MAG [ 4 ] - P [ 13 ] [ 1 ] * SK_MX [ 2 ] + P [ 13 ] [ 2 ] * SK_MX [ 1 ] + P [ 13 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 14 ] = SK_MX [ 0 ] * ( P [ 14 ] [ 19 ] + P [ 14 ] [ 16 ] * SH_MAG [ 1 ] + P [ 14 ] [ 17 ] * SH_MAG [ 4 ] - P [ 14 ] [ 1 ] * SK_MX [ 2 ] + P [ 14 ] [ 2 ] * SK_MX [ 1 ] + P [ 14 ] [ 18 ] * SK_MX [ 3 ] ) ;
2015-10-15 07:17:07 -03:00
Kfusion [ 15 ] = SK_MX [ 0 ] * ( P [ 15 ] [ 19 ] + P [ 15 ] [ 16 ] * SH_MAG [ 1 ] + P [ 15 ] [ 17 ] * SH_MAG [ 4 ] - P [ 15 ] [ 1 ] * SK_MX [ 2 ] + P [ 15 ] [ 2 ] * SK_MX [ 1 ] + P [ 15 ] [ 18 ] * SK_MX [ 3 ] ) ;
2015-10-19 18:32:07 -03:00
// end perf block
2015-10-05 23:30:07 -03:00
// zero Kalman gains to inhibit wind state estimation
if ( ! inhibitWindStates ) {
Kfusion [ 22 ] = SK_MX [ 0 ] * ( P [ 22 ] [ 19 ] + P [ 22 ] [ 16 ] * SH_MAG [ 1 ] + P [ 22 ] [ 17 ] * SH_MAG [ 4 ] - P [ 22 ] [ 1 ] * SK_MX [ 2 ] + P [ 22 ] [ 2 ] * SK_MX [ 1 ] + P [ 22 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 23 ] = SK_MX [ 0 ] * ( P [ 23 ] [ 19 ] + P [ 23 ] [ 16 ] * SH_MAG [ 1 ] + P [ 23 ] [ 17 ] * SH_MAG [ 4 ] - P [ 23 ] [ 1 ] * SK_MX [ 2 ] + P [ 23 ] [ 2 ] * SK_MX [ 1 ] + P [ 23 ] [ 18 ] * SK_MX [ 3 ] ) ;
} else {
Kfusion [ 22 ] = 0.0f ;
Kfusion [ 23 ] = 0.0f ;
}
// zero Kalman gains to inhibit magnetic field state estimation
if ( ! inhibitMagStates ) {
Kfusion [ 16 ] = SK_MX [ 0 ] * ( P [ 16 ] [ 19 ] + P [ 16 ] [ 16 ] * SH_MAG [ 1 ] + P [ 16 ] [ 17 ] * SH_MAG [ 4 ] - P [ 16 ] [ 1 ] * SK_MX [ 2 ] + P [ 16 ] [ 2 ] * SK_MX [ 1 ] + P [ 16 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 17 ] = SK_MX [ 0 ] * ( P [ 17 ] [ 19 ] + P [ 17 ] [ 16 ] * SH_MAG [ 1 ] + P [ 17 ] [ 17 ] * SH_MAG [ 4 ] - P [ 17 ] [ 1 ] * SK_MX [ 2 ] + P [ 17 ] [ 2 ] * SK_MX [ 1 ] + P [ 17 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 18 ] = SK_MX [ 0 ] * ( P [ 18 ] [ 19 ] + P [ 18 ] [ 16 ] * SH_MAG [ 1 ] + P [ 18 ] [ 17 ] * SH_MAG [ 4 ] - P [ 18 ] [ 1 ] * SK_MX [ 2 ] + P [ 18 ] [ 2 ] * SK_MX [ 1 ] + P [ 18 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 19 ] = SK_MX [ 0 ] * ( P [ 19 ] [ 19 ] + P [ 19 ] [ 16 ] * SH_MAG [ 1 ] + P [ 19 ] [ 17 ] * SH_MAG [ 4 ] - P [ 19 ] [ 1 ] * SK_MX [ 2 ] + P [ 19 ] [ 2 ] * SK_MX [ 1 ] + P [ 19 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 20 ] = SK_MX [ 0 ] * ( P [ 20 ] [ 19 ] + P [ 20 ] [ 16 ] * SH_MAG [ 1 ] + P [ 20 ] [ 17 ] * SH_MAG [ 4 ] - P [ 20 ] [ 1 ] * SK_MX [ 2 ] + P [ 20 ] [ 2 ] * SK_MX [ 1 ] + P [ 20 ] [ 18 ] * SK_MX [ 3 ] ) ;
Kfusion [ 21 ] = SK_MX [ 0 ] * ( P [ 21 ] [ 19 ] + P [ 21 ] [ 16 ] * SH_MAG [ 1 ] + P [ 21 ] [ 17 ] * SH_MAG [ 4 ] - P [ 21 ] [ 1 ] * SK_MX [ 2 ] + P [ 21 ] [ 2 ] * SK_MX [ 1 ] + P [ 21 ] [ 18 ] * SK_MX [ 3 ] ) ;
} else {
for ( uint8_t i = 16 ; i < = 21 ; i + + ) {
Kfusion [ i ] = 0.0f ;
}
}
// reset the observation index to 0 (we start by fusing the X measurement)
obsIndex = 0 ;
// set flags to indicate to other processes that fusion has been performed and is required on the next frame
// this can be used by other fusion processes to avoid fusing on the same frame as this expensive step
magFusePerformed = true ;
magFuseRequired = true ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 2 ] ) ;
2015-10-05 23:30:07 -03:00
}
else if ( obsIndex = = 1 ) // we are now fusing the Y measurement
{
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
// calculate observation jacobians
for ( uint8_t i = 0 ; i < = stateIndexLim ; i + + ) H_MAG [ i ] = 0.0f ;
H_MAG [ 0 ] = magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ;
H_MAG [ 2 ] = - magE * SH_MAG [ 4 ] - magD * SH_MAG [ 7 ] - magN * SH_MAG [ 1 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 16 ] = 2.0f * q1 * q2 - SH_MAG [ 8 ] ;
2015-10-05 23:30:07 -03:00
H_MAG [ 17 ] = SH_MAG [ 0 ] ;
H_MAG [ 18 ] = SH_MAG [ 3 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 20 ] = 1.0f ;
2015-10-05 23:30:07 -03:00
// calculate Kalman gain
2015-10-19 05:29:11 -03:00
varInnovMag [ 1 ] = ( P [ 20 ] [ 20 ] + R_MAG + P [ 0 ] [ 20 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 17 ] [ 20 ] * SH_MAG [ 0 ] + P [ 18 ] [ 20 ] * SH_MAG [ 3 ] - ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) * ( P [ 20 ] [ 16 ] + P [ 0 ] [ 16 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 17 ] [ 16 ] * SH_MAG [ 0 ] + P [ 18 ] [ 16 ] * SH_MAG [ 3 ] - P [ 2 ] [ 16 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 16 ] [ 16 ] * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) - P [ 2 ] [ 20 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) + ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) * ( P [ 20 ] [ 0 ] + P [ 0 ] [ 0 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 17 ] [ 0 ] * SH_MAG [ 0 ] + P [ 18 ] [ 0 ] * SH_MAG [ 3 ] - P [ 2 ] [ 0 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 16 ] [ 0 ] * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + SH_MAG [ 0 ] * ( P [ 20 ] [ 17 ] + P [ 0 ] [ 17 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 17 ] [ 17 ] * SH_MAG [ 0 ] + P [ 18 ] [ 17 ] * SH_MAG [ 3 ] - P [ 2 ] [ 17 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 16 ] [ 17 ] * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + SH_MAG [ 3 ] * ( P [ 20 ] [ 18 ] + P [ 0 ] [ 18 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 17 ] [ 18 ] * SH_MAG [ 0 ] + P [ 18 ] [ 18 ] * SH_MAG [ 3 ] - P [ 2 ] [ 18 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 16 ] [ 18 ] * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) - P [ 16 ] [ 20 ] * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) - ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) * ( P [ 20 ] [ 2 ] + P [ 0 ] [ 2 ] * ( magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ) + P [ 17 ] [ 2 ] * SH_MAG [ 0 ] + P [ 18 ] [ 2 ] * SH_MAG [ 3 ] - P [ 2 ] [ 2 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 16 ] [ 2 ] * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) ) ;
2015-10-05 23:30:07 -03:00
if ( varInnovMag [ 1 ] > = R_MAG ) {
SK_MY [ 0 ] = 1.0f / varInnovMag [ 1 ] ;
faultStatus . bad_ymag = 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 ( ) ;
obsIndex = 2 ;
faultStatus . bad_ymag = true ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
return ;
}
SK_MY [ 1 ] = magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ;
SK_MY [ 2 ] = magD * SH_MAG [ 2 ] - SH_MAG [ 6 ] + magN * SH_MAG [ 5 ] ;
2015-10-19 05:29:11 -03:00
SK_MY [ 3 ] = SH_MAG [ 8 ] - 2.0f * q1 * q2 ;
2015-10-05 23:30:07 -03:00
Kfusion [ 0 ] = SK_MY [ 0 ] * ( P [ 0 ] [ 20 ] + P [ 0 ] [ 17 ] * SH_MAG [ 0 ] + P [ 0 ] [ 18 ] * SH_MAG [ 3 ] + P [ 0 ] [ 0 ] * SK_MY [ 2 ] - P [ 0 ] [ 2 ] * SK_MY [ 1 ] - P [ 0 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 1 ] = SK_MY [ 0 ] * ( P [ 1 ] [ 20 ] + P [ 1 ] [ 17 ] * SH_MAG [ 0 ] + P [ 1 ] [ 18 ] * SH_MAG [ 3 ] + P [ 1 ] [ 0 ] * SK_MY [ 2 ] - P [ 1 ] [ 2 ] * SK_MY [ 1 ] - P [ 1 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 2 ] = SK_MY [ 0 ] * ( P [ 2 ] [ 20 ] + P [ 2 ] [ 17 ] * SH_MAG [ 0 ] + P [ 2 ] [ 18 ] * SH_MAG [ 3 ] + P [ 2 ] [ 0 ] * SK_MY [ 2 ] - P [ 2 ] [ 2 ] * SK_MY [ 1 ] - P [ 2 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 3 ] = SK_MY [ 0 ] * ( P [ 3 ] [ 20 ] + P [ 3 ] [ 17 ] * SH_MAG [ 0 ] + P [ 3 ] [ 18 ] * SH_MAG [ 3 ] + P [ 3 ] [ 0 ] * SK_MY [ 2 ] - P [ 3 ] [ 2 ] * SK_MY [ 1 ] - P [ 3 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 4 ] = SK_MY [ 0 ] * ( P [ 4 ] [ 20 ] + P [ 4 ] [ 17 ] * SH_MAG [ 0 ] + P [ 4 ] [ 18 ] * SH_MAG [ 3 ] + P [ 4 ] [ 0 ] * SK_MY [ 2 ] - P [ 4 ] [ 2 ] * SK_MY [ 1 ] - P [ 4 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 5 ] = SK_MY [ 0 ] * ( P [ 5 ] [ 20 ] + P [ 5 ] [ 17 ] * SH_MAG [ 0 ] + P [ 5 ] [ 18 ] * SH_MAG [ 3 ] + P [ 5 ] [ 0 ] * SK_MY [ 2 ] - P [ 5 ] [ 2 ] * SK_MY [ 1 ] - P [ 5 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 6 ] = SK_MY [ 0 ] * ( P [ 6 ] [ 20 ] + P [ 6 ] [ 17 ] * SH_MAG [ 0 ] + P [ 6 ] [ 18 ] * SH_MAG [ 3 ] + P [ 6 ] [ 0 ] * SK_MY [ 2 ] - P [ 6 ] [ 2 ] * SK_MY [ 1 ] - P [ 6 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 7 ] = SK_MY [ 0 ] * ( P [ 7 ] [ 20 ] + P [ 7 ] [ 17 ] * SH_MAG [ 0 ] + P [ 7 ] [ 18 ] * SH_MAG [ 3 ] + P [ 7 ] [ 0 ] * SK_MY [ 2 ] - P [ 7 ] [ 2 ] * SK_MY [ 1 ] - P [ 7 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 8 ] = SK_MY [ 0 ] * ( P [ 8 ] [ 20 ] + P [ 8 ] [ 17 ] * SH_MAG [ 0 ] + P [ 8 ] [ 18 ] * SH_MAG [ 3 ] + P [ 8 ] [ 0 ] * SK_MY [ 2 ] - P [ 8 ] [ 2 ] * SK_MY [ 1 ] - P [ 8 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 9 ] = SK_MY [ 0 ] * ( P [ 9 ] [ 20 ] + P [ 9 ] [ 17 ] * SH_MAG [ 0 ] + P [ 9 ] [ 18 ] * SH_MAG [ 3 ] + P [ 9 ] [ 0 ] * SK_MY [ 2 ] - P [ 9 ] [ 2 ] * SK_MY [ 1 ] - P [ 9 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 10 ] = SK_MY [ 0 ] * ( P [ 10 ] [ 20 ] + P [ 10 ] [ 17 ] * SH_MAG [ 0 ] + P [ 10 ] [ 18 ] * SH_MAG [ 3 ] + P [ 10 ] [ 0 ] * SK_MY [ 2 ] - P [ 10 ] [ 2 ] * SK_MY [ 1 ] - P [ 10 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 11 ] = SK_MY [ 0 ] * ( P [ 11 ] [ 20 ] + P [ 11 ] [ 17 ] * SH_MAG [ 0 ] + P [ 11 ] [ 18 ] * SH_MAG [ 3 ] + P [ 11 ] [ 0 ] * SK_MY [ 2 ] - P [ 11 ] [ 2 ] * SK_MY [ 1 ] - P [ 11 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 12 ] = SK_MY [ 0 ] * ( P [ 12 ] [ 20 ] + P [ 12 ] [ 17 ] * SH_MAG [ 0 ] + P [ 12 ] [ 18 ] * SH_MAG [ 3 ] + P [ 12 ] [ 0 ] * SK_MY [ 2 ] - P [ 12 ] [ 2 ] * SK_MY [ 1 ] - P [ 12 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 13 ] = SK_MY [ 0 ] * ( P [ 13 ] [ 20 ] + P [ 13 ] [ 17 ] * SH_MAG [ 0 ] + P [ 13 ] [ 18 ] * SH_MAG [ 3 ] + P [ 13 ] [ 0 ] * SK_MY [ 2 ] - P [ 13 ] [ 2 ] * SK_MY [ 1 ] - P [ 13 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 14 ] = SK_MY [ 0 ] * ( P [ 14 ] [ 20 ] + P [ 14 ] [ 17 ] * SH_MAG [ 0 ] + P [ 14 ] [ 18 ] * SH_MAG [ 3 ] + P [ 14 ] [ 0 ] * SK_MY [ 2 ] - P [ 14 ] [ 2 ] * SK_MY [ 1 ] - P [ 14 ] [ 16 ] * SK_MY [ 3 ] ) ;
2015-10-15 07:17:07 -03:00
Kfusion [ 15 ] = SK_MY [ 0 ] * ( P [ 15 ] [ 20 ] + P [ 15 ] [ 17 ] * SH_MAG [ 0 ] + P [ 15 ] [ 18 ] * SH_MAG [ 3 ] + P [ 15 ] [ 0 ] * SK_MY [ 2 ] - P [ 15 ] [ 2 ] * SK_MY [ 1 ] - P [ 15 ] [ 16 ] * SK_MY [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
// zero Kalman gains to inhibit wind state estimation
if ( ! inhibitWindStates ) {
Kfusion [ 22 ] = SK_MY [ 0 ] * ( P [ 22 ] [ 20 ] + P [ 22 ] [ 17 ] * SH_MAG [ 0 ] + P [ 22 ] [ 18 ] * SH_MAG [ 3 ] + P [ 22 ] [ 0 ] * SK_MY [ 2 ] - P [ 22 ] [ 2 ] * SK_MY [ 1 ] - P [ 22 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 23 ] = SK_MY [ 0 ] * ( P [ 23 ] [ 20 ] + P [ 23 ] [ 17 ] * SH_MAG [ 0 ] + P [ 23 ] [ 18 ] * SH_MAG [ 3 ] + P [ 23 ] [ 0 ] * SK_MY [ 2 ] - P [ 23 ] [ 2 ] * SK_MY [ 1 ] - P [ 23 ] [ 16 ] * SK_MY [ 3 ] ) ;
} else {
Kfusion [ 22 ] = 0.0f ;
Kfusion [ 23 ] = 0.0f ;
}
// zero Kalman gains to inhibit magnetic field state estimation
if ( ! inhibitMagStates ) {
Kfusion [ 16 ] = SK_MY [ 0 ] * ( P [ 16 ] [ 20 ] + P [ 16 ] [ 17 ] * SH_MAG [ 0 ] + P [ 16 ] [ 18 ] * SH_MAG [ 3 ] + P [ 16 ] [ 0 ] * SK_MY [ 2 ] - P [ 16 ] [ 2 ] * SK_MY [ 1 ] - P [ 16 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 17 ] = SK_MY [ 0 ] * ( P [ 17 ] [ 20 ] + P [ 17 ] [ 17 ] * SH_MAG [ 0 ] + P [ 17 ] [ 18 ] * SH_MAG [ 3 ] + P [ 17 ] [ 0 ] * SK_MY [ 2 ] - P [ 17 ] [ 2 ] * SK_MY [ 1 ] - P [ 17 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 18 ] = SK_MY [ 0 ] * ( P [ 18 ] [ 20 ] + P [ 18 ] [ 17 ] * SH_MAG [ 0 ] + P [ 18 ] [ 18 ] * SH_MAG [ 3 ] + P [ 18 ] [ 0 ] * SK_MY [ 2 ] - P [ 18 ] [ 2 ] * SK_MY [ 1 ] - P [ 18 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 19 ] = SK_MY [ 0 ] * ( P [ 19 ] [ 20 ] + P [ 19 ] [ 17 ] * SH_MAG [ 0 ] + P [ 19 ] [ 18 ] * SH_MAG [ 3 ] + P [ 19 ] [ 0 ] * SK_MY [ 2 ] - P [ 19 ] [ 2 ] * SK_MY [ 1 ] - P [ 19 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 20 ] = SK_MY [ 0 ] * ( P [ 20 ] [ 20 ] + P [ 20 ] [ 17 ] * SH_MAG [ 0 ] + P [ 20 ] [ 18 ] * SH_MAG [ 3 ] + P [ 20 ] [ 0 ] * SK_MY [ 2 ] - P [ 20 ] [ 2 ] * SK_MY [ 1 ] - P [ 20 ] [ 16 ] * SK_MY [ 3 ] ) ;
Kfusion [ 21 ] = SK_MY [ 0 ] * ( P [ 21 ] [ 20 ] + P [ 21 ] [ 17 ] * SH_MAG [ 0 ] + P [ 21 ] [ 18 ] * SH_MAG [ 3 ] + P [ 21 ] [ 0 ] * SK_MY [ 2 ] - P [ 21 ] [ 2 ] * SK_MY [ 1 ] - P [ 21 ] [ 16 ] * SK_MY [ 3 ] ) ;
} else {
for ( uint8_t i = 16 ; i < = 21 ; i + + ) {
Kfusion [ i ] = 0.0f ;
}
}
// set flags to indicate to other processes that fusion has been performede and is required on the next frame
// this can be used by other fusion processes to avoid fusing on the same frame as this expensive step
magFusePerformed = true ;
magFuseRequired = true ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
}
else if ( obsIndex = = 2 ) // we are now fusing the Z measurement
{
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 4 ] ) ;
2015-10-05 23:30:07 -03:00
// calculate observation jacobians
for ( uint8_t i = 0 ; i < = stateIndexLim ; i + + ) H_MAG [ i ] = 0.0f ;
2015-10-19 05:29:11 -03:00
H_MAG [ 0 ] = magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) - magD * SH_MAG [ 3 ] - magE * SH_MAG [ 0 ] ;
2015-10-16 07:03:08 -03:00
H_MAG [ 1 ] = magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ;
2015-10-05 23:30:07 -03:00
H_MAG [ 16 ] = SH_MAG [ 5 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 17 ] = 2.0f * q2 * q3 - 2.0f * q0 * q1 ;
2015-10-05 23:30:07 -03:00
H_MAG [ 18 ] = SH_MAG [ 2 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 21 ] = 1.0f ;
2015-10-05 23:30:07 -03:00
// calculate Kalman gain
2015-10-19 05:29:11 -03:00
varInnovMag [ 2 ] = ( P [ 21 ] [ 21 ] + R_MAG + P [ 16 ] [ 21 ] * SH_MAG [ 5 ] + P [ 18 ] [ 21 ] * SH_MAG [ 2 ] - ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) * ( P [ 21 ] [ 17 ] + P [ 16 ] [ 17 ] * SH_MAG [ 5 ] + P [ 18 ] [ 17 ] * SH_MAG [ 2 ] - P [ 0 ] [ 17 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + P [ 1 ] [ 17 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 17 ] [ 17 ] * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) ) - P [ 0 ] [ 21 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + P [ 1 ] [ 21 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) + SH_MAG [ 5 ] * ( P [ 21 ] [ 16 ] + P [ 16 ] [ 16 ] * SH_MAG [ 5 ] + P [ 18 ] [ 16 ] * SH_MAG [ 2 ] - P [ 0 ] [ 16 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + P [ 1 ] [ 16 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 17 ] [ 16 ] * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) ) + SH_MAG [ 2 ] * ( P [ 21 ] [ 18 ] + P [ 16 ] [ 18 ] * SH_MAG [ 5 ] + P [ 18 ] [ 18 ] * SH_MAG [ 2 ] - P [ 0 ] [ 18 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + P [ 1 ] [ 18 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 17 ] [ 18 ] * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) ) - ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) * ( P [ 21 ] [ 0 ] + P [ 16 ] [ 0 ] * SH_MAG [ 5 ] + P [ 18 ] [ 0 ] * SH_MAG [ 2 ] - P [ 0 ] [ 0 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + P [ 1 ] [ 0 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 17 ] [ 0 ] * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) ) - P [ 17 ] [ 21 ] * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) + ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) * ( P [ 21 ] [ 1 ] + P [ 16 ] [ 1 ] * SH_MAG [ 5 ] + P [ 18 ] [ 1 ] * SH_MAG [ 2 ] - P [ 0 ] [ 1 ] * ( magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ) + P [ 1 ] [ 1 ] * ( magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ) - P [ 17 ] [ 1 ] * ( 2.0f * q0 * q1 - 2.0f * q2 * q3 ) ) ) ;
2015-10-05 23:30:07 -03:00
if ( varInnovMag [ 2 ] > = R_MAG ) {
SK_MZ [ 0 ] = 1.0f / varInnovMag [ 2 ] ;
faultStatus . bad_zmag = 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 ( ) ;
obsIndex = 3 ;
faultStatus . bad_zmag = true ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 4 ] ) ;
2015-10-05 23:30:07 -03:00
return ;
}
2015-10-19 05:29:11 -03:00
SK_MZ [ 1 ] = magE * SH_MAG [ 0 ] + magD * SH_MAG [ 3 ] - magN * ( SH_MAG [ 8 ] - 2.0f * q1 * q2 ) ;
2015-10-16 07:03:08 -03:00
SK_MZ [ 2 ] = magE * SH_MAG [ 4 ] + magD * SH_MAG [ 7 ] + magN * SH_MAG [ 1 ] ;
2015-10-19 05:29:11 -03:00
SK_MZ [ 3 ] = 2.0f * q0 * q1 - 2.0f * q2 * q3 ;
2015-10-16 07:03:08 -03:00
Kfusion [ 0 ] = SK_MZ [ 0 ] * ( P [ 0 ] [ 21 ] + P [ 0 ] [ 18 ] * SH_MAG [ 2 ] + P [ 0 ] [ 16 ] * SH_MAG [ 5 ] - P [ 0 ] [ 0 ] * SK_MZ [ 1 ] + P [ 0 ] [ 1 ] * SK_MZ [ 2 ] - P [ 0 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 1 ] = SK_MZ [ 0 ] * ( P [ 1 ] [ 21 ] + P [ 1 ] [ 18 ] * SH_MAG [ 2 ] + P [ 1 ] [ 16 ] * SH_MAG [ 5 ] - P [ 1 ] [ 0 ] * SK_MZ [ 1 ] + P [ 1 ] [ 1 ] * SK_MZ [ 2 ] - P [ 1 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 2 ] = SK_MZ [ 0 ] * ( P [ 2 ] [ 21 ] + P [ 2 ] [ 18 ] * SH_MAG [ 2 ] + P [ 2 ] [ 16 ] * SH_MAG [ 5 ] - P [ 2 ] [ 0 ] * SK_MZ [ 1 ] + P [ 2 ] [ 1 ] * SK_MZ [ 2 ] - P [ 2 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 3 ] = SK_MZ [ 0 ] * ( P [ 3 ] [ 21 ] + P [ 3 ] [ 18 ] * SH_MAG [ 2 ] + P [ 3 ] [ 16 ] * SH_MAG [ 5 ] - P [ 3 ] [ 0 ] * SK_MZ [ 1 ] + P [ 3 ] [ 1 ] * SK_MZ [ 2 ] - P [ 3 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 4 ] = SK_MZ [ 0 ] * ( P [ 4 ] [ 21 ] + P [ 4 ] [ 18 ] * SH_MAG [ 2 ] + P [ 4 ] [ 16 ] * SH_MAG [ 5 ] - P [ 4 ] [ 0 ] * SK_MZ [ 1 ] + P [ 4 ] [ 1 ] * SK_MZ [ 2 ] - P [ 4 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 5 ] = SK_MZ [ 0 ] * ( P [ 5 ] [ 21 ] + P [ 5 ] [ 18 ] * SH_MAG [ 2 ] + P [ 5 ] [ 16 ] * SH_MAG [ 5 ] - P [ 5 ] [ 0 ] * SK_MZ [ 1 ] + P [ 5 ] [ 1 ] * SK_MZ [ 2 ] - P [ 5 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 6 ] = SK_MZ [ 0 ] * ( P [ 6 ] [ 21 ] + P [ 6 ] [ 18 ] * SH_MAG [ 2 ] + P [ 6 ] [ 16 ] * SH_MAG [ 5 ] - P [ 6 ] [ 0 ] * SK_MZ [ 1 ] + P [ 6 ] [ 1 ] * SK_MZ [ 2 ] - P [ 6 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 7 ] = SK_MZ [ 0 ] * ( P [ 7 ] [ 21 ] + P [ 7 ] [ 18 ] * SH_MAG [ 2 ] + P [ 7 ] [ 16 ] * SH_MAG [ 5 ] - P [ 7 ] [ 0 ] * SK_MZ [ 1 ] + P [ 7 ] [ 1 ] * SK_MZ [ 2 ] - P [ 7 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 8 ] = SK_MZ [ 0 ] * ( P [ 8 ] [ 21 ] + P [ 8 ] [ 18 ] * SH_MAG [ 2 ] + P [ 8 ] [ 16 ] * SH_MAG [ 5 ] - P [ 8 ] [ 0 ] * SK_MZ [ 1 ] + P [ 8 ] [ 1 ] * SK_MZ [ 2 ] - P [ 8 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 9 ] = SK_MZ [ 0 ] * ( P [ 9 ] [ 21 ] + P [ 9 ] [ 18 ] * SH_MAG [ 2 ] + P [ 9 ] [ 16 ] * SH_MAG [ 5 ] - P [ 9 ] [ 0 ] * SK_MZ [ 1 ] + P [ 9 ] [ 1 ] * SK_MZ [ 2 ] - P [ 9 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 10 ] = SK_MZ [ 0 ] * ( P [ 10 ] [ 21 ] + P [ 10 ] [ 18 ] * SH_MAG [ 2 ] + P [ 10 ] [ 16 ] * SH_MAG [ 5 ] - P [ 10 ] [ 0 ] * SK_MZ [ 1 ] + P [ 10 ] [ 1 ] * SK_MZ [ 2 ] - P [ 10 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 11 ] = SK_MZ [ 0 ] * ( P [ 11 ] [ 21 ] + P [ 11 ] [ 18 ] * SH_MAG [ 2 ] + P [ 11 ] [ 16 ] * SH_MAG [ 5 ] - P [ 11 ] [ 0 ] * SK_MZ [ 1 ] + P [ 11 ] [ 1 ] * SK_MZ [ 2 ] - P [ 11 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 12 ] = SK_MZ [ 0 ] * ( P [ 12 ] [ 21 ] + P [ 12 ] [ 18 ] * SH_MAG [ 2 ] + P [ 12 ] [ 16 ] * SH_MAG [ 5 ] - P [ 12 ] [ 0 ] * SK_MZ [ 1 ] + P [ 12 ] [ 1 ] * SK_MZ [ 2 ] - P [ 12 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 13 ] = SK_MZ [ 0 ] * ( P [ 13 ] [ 21 ] + P [ 13 ] [ 18 ] * SH_MAG [ 2 ] + P [ 13 ] [ 16 ] * SH_MAG [ 5 ] - P [ 13 ] [ 0 ] * SK_MZ [ 1 ] + P [ 13 ] [ 1 ] * SK_MZ [ 2 ] - P [ 13 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 14 ] = SK_MZ [ 0 ] * ( P [ 14 ] [ 21 ] + P [ 14 ] [ 18 ] * SH_MAG [ 2 ] + P [ 14 ] [ 16 ] * SH_MAG [ 5 ] - P [ 14 ] [ 0 ] * SK_MZ [ 1 ] + P [ 14 ] [ 1 ] * SK_MZ [ 2 ] - P [ 14 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 15 ] = SK_MZ [ 0 ] * ( P [ 15 ] [ 21 ] + P [ 15 ] [ 18 ] * SH_MAG [ 2 ] + P [ 15 ] [ 16 ] * SH_MAG [ 5 ] - P [ 15 ] [ 0 ] * SK_MZ [ 1 ] + P [ 15 ] [ 1 ] * SK_MZ [ 2 ] - P [ 15 ] [ 17 ] * SK_MZ [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
// zero Kalman gains to inhibit wind state estimation
if ( ! inhibitWindStates ) {
2015-10-16 07:03:08 -03:00
Kfusion [ 22 ] = SK_MZ [ 0 ] * ( P [ 22 ] [ 21 ] + P [ 22 ] [ 18 ] * SH_MAG [ 2 ] + P [ 22 ] [ 16 ] * SH_MAG [ 5 ] - P [ 22 ] [ 0 ] * SK_MZ [ 1 ] + P [ 22 ] [ 1 ] * SK_MZ [ 2 ] - P [ 22 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 23 ] = SK_MZ [ 0 ] * ( P [ 23 ] [ 21 ] + P [ 23 ] [ 18 ] * SH_MAG [ 2 ] + P [ 23 ] [ 16 ] * SH_MAG [ 5 ] - P [ 23 ] [ 0 ] * SK_MZ [ 1 ] + P [ 23 ] [ 1 ] * SK_MZ [ 2 ] - P [ 23 ] [ 17 ] * SK_MZ [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
} else {
Kfusion [ 22 ] = 0.0f ;
Kfusion [ 23 ] = 0.0f ;
}
// zero Kalman gains to inhibit magnetic field state estimation
if ( ! inhibitMagStates ) {
2015-10-16 07:03:08 -03:00
Kfusion [ 16 ] = SK_MZ [ 0 ] * ( P [ 16 ] [ 21 ] + P [ 16 ] [ 18 ] * SH_MAG [ 2 ] + P [ 16 ] [ 16 ] * SH_MAG [ 5 ] - P [ 16 ] [ 0 ] * SK_MZ [ 1 ] + P [ 16 ] [ 1 ] * SK_MZ [ 2 ] - P [ 16 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 17 ] = SK_MZ [ 0 ] * ( P [ 17 ] [ 21 ] + P [ 17 ] [ 18 ] * SH_MAG [ 2 ] + P [ 17 ] [ 16 ] * SH_MAG [ 5 ] - P [ 17 ] [ 0 ] * SK_MZ [ 1 ] + P [ 17 ] [ 1 ] * SK_MZ [ 2 ] - P [ 17 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 18 ] = SK_MZ [ 0 ] * ( P [ 18 ] [ 21 ] + P [ 18 ] [ 18 ] * SH_MAG [ 2 ] + P [ 18 ] [ 16 ] * SH_MAG [ 5 ] - P [ 18 ] [ 0 ] * SK_MZ [ 1 ] + P [ 18 ] [ 1 ] * SK_MZ [ 2 ] - P [ 18 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 19 ] = SK_MZ [ 0 ] * ( P [ 19 ] [ 21 ] + P [ 19 ] [ 18 ] * SH_MAG [ 2 ] + P [ 19 ] [ 16 ] * SH_MAG [ 5 ] - P [ 19 ] [ 0 ] * SK_MZ [ 1 ] + P [ 19 ] [ 1 ] * SK_MZ [ 2 ] - P [ 19 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 20 ] = SK_MZ [ 0 ] * ( P [ 20 ] [ 21 ] + P [ 20 ] [ 18 ] * SH_MAG [ 2 ] + P [ 20 ] [ 16 ] * SH_MAG [ 5 ] - P [ 20 ] [ 0 ] * SK_MZ [ 1 ] + P [ 20 ] [ 1 ] * SK_MZ [ 2 ] - P [ 20 ] [ 17 ] * SK_MZ [ 3 ] ) ;
Kfusion [ 21 ] = SK_MZ [ 0 ] * ( P [ 21 ] [ 21 ] + P [ 21 ] [ 18 ] * SH_MAG [ 2 ] + P [ 21 ] [ 16 ] * SH_MAG [ 5 ] - P [ 21 ] [ 0 ] * SK_MZ [ 1 ] + P [ 21 ] [ 1 ] * SK_MZ [ 2 ] - P [ 21 ] [ 17 ] * SK_MZ [ 3 ] ) ;
2015-10-05 23:30:07 -03:00
} else {
for ( uint8_t i = 16 ; i < = 21 ; i + + ) {
Kfusion [ i ] = 0.0f ;
}
}
// set flags to indicate to other processes that fusion has been performede and is required on the next frame
// this can be used by other fusion processes to avoid fusing on the same frame as this expensive step
magFusePerformed = true ;
magFuseRequired = false ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 4 ] ) ;
2015-10-05 23:30:07 -03:00
}
2015-10-19 18:32:07 -03:00
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 5 ] ) ;
2015-10-05 23:30:07 -03:00
// calculate the measurement innovation
innovMag [ obsIndex ] = MagPred [ obsIndex ] - magDataDelayed . mag [ obsIndex ] ;
// calculate the innovation test ratio
2015-10-30 03:07:38 -03:00
magTestRatio [ obsIndex ] = sq ( innovMag [ obsIndex ] ) / ( sq ( max ( frontend . _magInnovGate , 1 ) ) * varInnovMag [ obsIndex ] ) ;
2015-10-05 23:30:07 -03:00
// check the last values from all components and set magnetometer health accordingly
magHealth = ( magTestRatio [ 0 ] < 1.0f & & magTestRatio [ 1 ] < 1.0f & & magTestRatio [ 2 ] < 1.0f ) ;
// Don't fuse unless all componenets pass. The exception is if the bad health has timed out and we are not a fly forward vehicle
// In this case we might as well try using the magnetometer, but with a reduced weighting
if ( magHealth | | ( ( magTestRatio [ obsIndex ] < 1.0f ) & & ! assume_zero_sideslip ( ) & & magTimeout ) ) {
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 8 ] ) ;
2015-10-19 18:32:07 -03:00
2015-10-05 23:30:07 -03:00
// zero the attitude error state - by definition it is assumed to be zero before each observaton fusion
stateStruct . angErr . zero ( ) ;
// correct the state vector
for ( uint8_t j = 0 ; j < = stateIndexLim ; j + + ) {
// If we are forced to use a bad compass in flight, we reduce the weighting by a factor of 4
if ( ! magHealth & & ( PV_AidingMode = = AID_ABSOLUTE ) ) {
Kfusion [ j ] * = 0.25f ;
}
statesArray [ j ] = statesArray [ j ] - Kfusion [ j ] * innovMag [ obsIndex ] ;
}
2015-10-22 20:15:23 -03:00
// Inhibit corrections to tilt if requested. This enables mag states to settle after a reset without causing sudden changes in roll and pitch
if ( magFuseTiltInhibit ) {
stateStruct . angErr . x = 0.0f ;
stateStruct . angErr . y = 0.0f ;
}
2015-10-05 23:30:07 -03:00
// the first 3 states represent the angular misalignment vector. This is
// is used to correct the estimated quaternion on the current time step
stateStruct . quat . rotate ( stateStruct . angErr ) ;
// correct the covariance P = (I - K*H)*P
// take advantage of the empty columns in KH to reduce the
// number of operations
2015-10-19 23:02:28 -03:00
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = 2 ; j + + ) {
2015-10-05 23:30:07 -03:00
KH [ i ] [ j ] = Kfusion [ i ] * H_MAG [ j ] ;
}
2015-10-19 23:02:28 -03:00
for ( unsigned j = 3 ; j < = 15 ; j + + ) {
2015-10-05 23:30:07 -03:00
KH [ i ] [ j ] = 0.0f ;
}
2015-10-19 23:02:28 -03:00
for ( unsigned j = 16 ; j < = 21 ; j + + ) {
KH [ i ] [ j ] = Kfusion [ i ] * H_MAG [ j ] ;
2015-10-05 23:30:07 -03:00
}
2015-10-19 23:02:28 -03:00
for ( unsigned j = 22 ; j < = 23 ; j + + ) {
2015-10-05 23:30:07 -03:00
KH [ i ] [ j ] = 0.0f ;
}
}
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 8 ] ) ;
hal . util - > perf_begin ( _perf_test [ 9 ] ) ;
2015-10-19 18:32:07 -03:00
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
2015-10-19 18:57:39 -03:00
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 ] [ 16 ] * P [ 16 ] [ j ] ;
res + = KH [ i ] [ 17 ] * P [ 17 ] [ j ] ;
res + = KH [ i ] [ 18 ] * P [ 18 ] [ j ] ;
res + = KH [ i ] [ 19 ] * P [ 19 ] [ j ] ;
res + = KH [ i ] [ 20 ] * P [ 20 ] [ j ] ;
res + = KH [ i ] [ 21 ] * P [ 21 ] [ j ] ;
KHP [ i ] [ j ] = res ;
2015-10-05 23:30:07 -03:00
}
}
2015-10-19 18:57:39 -03:00
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
2015-10-05 23:30:07 -03:00
P [ i ] [ j ] = P [ i ] [ j ] - KHP [ i ] [ j ] ;
}
}
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 9 ] ) ;
2015-10-05 23:30:07 -03:00
}
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 5 ] ) ;
2015-10-05 23:30:07 -03:00
// force the covariance matrix to be symmetrical and limit the variances to prevent
// ill-condiioning.
2015-10-20 02:42:50 -03:00
hal . util - > perf_begin ( _perf_test [ 6 ] ) ;
2015-10-05 23:30:07 -03:00
ForceSymmetry ( ) ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 6 ] ) ;
hal . util - > perf_begin ( _perf_test [ 7 ] ) ;
2015-10-05 23:30:07 -03:00
ConstrainVariances ( ) ;
2015-10-20 02:42:50 -03:00
hal . util - > perf_end ( _perf_test [ 7 ] ) ;
2015-10-05 23:30:07 -03:00
}
2015-10-17 20:32:11 -03:00
/*
* Fuse compass 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 :
* https : //github.com/priseborough/InertialNav/blob/master/derivations/RotationVectorAttitudeParameterisation/GenerateNavFilterEquations.m
2015-10-18 19:37:47 -03:00
* This fusion method only modifies the orientation , does not require use of the magnetic field states and is computatonally cheaper .
* It is suitable for use when the external magnetic field environment is disturbed ( eg close to metal structures , on ground ) .
* It is not as robust to magneometer failures .
2015-10-17 20:32:11 -03:00
*/
2015-10-05 23:30:07 -03:00
void NavEKF2_core : : fuseCompass ( )
{
float q0 = stateStruct . quat [ 0 ] ;
float q1 = stateStruct . quat [ 1 ] ;
float q2 = stateStruct . quat [ 2 ] ;
float q3 = stateStruct . quat [ 3 ] ;
float magX = magDataDelayed . mag . x ;
float magY = magDataDelayed . mag . y ;
float magZ = magDataDelayed . mag . z ;
// compass measurement error variance (rad^2)
const float R_MAG = 3e-2 f ;
// Calculate observation Jacobian
float t2 = q0 * q0 ;
float t3 = q1 * q1 ;
float t4 = q2 * q2 ;
float t5 = q3 * q3 ;
float t6 = q0 * q2 * 2.0f ;
float t7 = q1 * q3 * 2.0f ;
float t8 = t6 + t7 ;
float t9 = q0 * q3 * 2.0f ;
float t13 = q1 * q2 * 2.0f ;
float t10 = t9 - t13 ;
float t11 = t2 + t3 - t4 - t5 ;
float t12 = magX * t11 ;
float t14 = magZ * t8 ;
float t19 = magY * t10 ;
float t15 = t12 + t14 - t19 ;
float t16 = t2 - t3 + t4 - t5 ;
float t17 = q0 * q1 * 2.0f ;
float t24 = q2 * q3 * 2.0f ;
float t18 = t17 - t24 ;
float t20 = 1.0f / t15 ;
float t21 = magY * t16 ;
float t22 = t9 + t13 ;
float t23 = magX * t22 ;
float t28 = magZ * t18 ;
float t25 = t21 + t23 - t28 ;
float t29 = t20 * t25 ;
float t26 = tan ( t29 ) ;
float t27 = 1.0f / ( t15 * t15 ) ;
float t30 = t26 * t26 ;
float t31 = t30 + 1.0f ;
float H_MAG [ 3 ] ;
H_MAG [ 0 ] = - t31 * ( t20 * ( magZ * t16 + magY * t18 ) + t25 * t27 * ( magY * t8 + magZ * t10 ) ) ;
H_MAG [ 1 ] = t31 * ( t20 * ( magX * t18 + magZ * t22 ) + t25 * t27 * ( magX * t8 - magZ * t11 ) ) ;
H_MAG [ 2 ] = t31 * ( t20 * ( magX * t16 - magY * t22 ) + t25 * t27 * ( magX * t10 + magY * t11 ) ) ;
// Calculate innovation variance and Kalman gains, taking advantage of the fact that only the first 3 elements in H are non zero
float PH [ 3 ] ;
float varInnov = R_MAG ;
for ( uint8_t rowIndex = 0 ; rowIndex < = 2 ; rowIndex + + ) {
PH [ rowIndex ] = 0.0f ;
for ( uint8_t colIndex = 0 ; colIndex < = 2 ; colIndex + + ) {
PH [ rowIndex ] + = P [ rowIndex ] [ colIndex ] * H_MAG [ colIndex ] ;
}
varInnov + = H_MAG [ rowIndex ] * PH [ rowIndex ] ;
}
2015-10-30 03:07:38 -03:00
float varInnovInv ;
if ( varInnov > = R_MAG ) {
varInnovInv = 1.0f / varInnov ;
// All three magnetometer components are used in this measurement, so we output health status on three axes
faultStatus . bad_xmag = false ;
faultStatus . bad_ymag = false ;
faultStatus . bad_zmag = 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 ( ) ;
// All three magnetometer components are used in this measurement, so we output health status on three axes
faultStatus . bad_xmag = true ;
faultStatus . bad_ymag = true ;
faultStatus . bad_zmag = true ;
return ;
}
2015-10-05 23:30:07 -03:00
for ( uint8_t rowIndex = 0 ; rowIndex < = stateIndexLim ; rowIndex + + ) {
Kfusion [ rowIndex ] = 0.0f ;
for ( uint8_t colIndex = 0 ; colIndex < = 2 ; colIndex + + ) {
Kfusion [ rowIndex ] + = P [ rowIndex ] [ colIndex ] * H_MAG [ colIndex ] ;
}
Kfusion [ rowIndex ] * = varInnovInv ;
}
// Calculate the innovation
float innovation = calcMagHeadingInnov ( ) ;
// Copy raw value to output variable used for data logging
innovYaw = innovation ;
// limit the innovation so that initial corrections are not too large
if ( innovation > 0.5f ) {
innovation = 0.5f ;
} else if ( innovation < - 0.5f ) {
innovation = - 0.5f ;
}
2015-10-28 22:36:53 -03:00
// calculate the innovation test ratio
2015-10-30 03:07:38 -03:00
yawTestRatio = sq ( innovation ) / ( sq ( max ( frontend . _magInnovGate , 1 ) ) * varInnov ) ;
2015-10-28 22:36:53 -03:00
// Declare the magnetometer unhealthy if the innovation test fails
if ( yawTestRatio > 1.0f ) {
magHealth = false ;
// On the ground a large innovation could be due to large initial gyro bias or magnetic interference from nearby objects
// If we are flying, then it is more likely due to a magnetometer fault and we should not fuse the data
if ( inFlight ) {
return ;
}
} else {
magHealth = true ;
}
2015-10-05 23:30:07 -03:00
// correct the state vector
stateStruct . angErr . zero ( ) ;
for ( uint8_t i = 0 ; i < = stateIndexLim ; i + + ) {
statesArray [ i ] - = Kfusion [ i ] * innovation ;
}
// the first 3 states represent the angular misalignment vector. This is
// is used to correct the estimated quaternion on the current time step
stateStruct . quat . rotate ( stateStruct . angErr ) ;
// correct the covariance using P = P - K*H*P taking advantage of the fact that only the first 3 elements in H are non zero
float HP [ 24 ] ;
for ( uint8_t colIndex = 0 ; colIndex < = stateIndexLim ; colIndex + + ) {
HP [ colIndex ] = 0.0f ;
for ( uint8_t rowIndex = 0 ; rowIndex < = 2 ; rowIndex + + ) {
HP [ colIndex ] + = H_MAG [ rowIndex ] * P [ rowIndex ] [ colIndex ] ;
}
}
for ( uint8_t rowIndex = 0 ; rowIndex < = stateIndexLim ; rowIndex + + ) {
for ( uint8_t colIndex = 0 ; colIndex < = stateIndexLim ; colIndex + + ) {
P [ rowIndex ] [ colIndex ] - = Kfusion [ rowIndex ] * HP [ colIndex ] ;
}
}
// force the covariance matrix to be symmetrical and limit the variances to prevent
// ill-condiioning.
ForceSymmetry ( ) ;
ConstrainVariances ( ) ;
}
2015-10-18 07:16:55 -03:00
/*
* Fuse declination angle 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 :
* https : //github.com/priseborough/InertialNav/blob/master/derivations/RotationVectorAttitudeParameterisation/GenerateNavFilterEquations.m
2015-10-18 19:37:47 -03:00
* This is used to prevent the declination of the EKF earth field states from drifting during operation without GPS
2015-10-18 07:16:55 -03:00
* or some other absolute position or velocity reference
*/
void NavEKF2_core : : FuseDeclination ( )
{
// declination error variance (rad^2)
const float R_DECL = 1e-2 f ;
// copy required states to local variables
float magN = stateStruct . earth_magfield . x ;
float magE = stateStruct . earth_magfield . y ;
// prevent bad earth field states from causing numerical errors or exceptions
if ( magN < 1e-3 f ) {
return ;
}
// Calculate observation Jacobian and Kalman gains
float t2 = 1.0f / magN ;
float t4 = magE * t2 ;
float t3 = tanf ( t4 ) ;
float t5 = t3 * t3 ;
2015-10-19 05:29:11 -03:00
float t6 = t5 + 1.0f ;
2015-10-18 07:16:55 -03:00
float t7 = 1.0f / ( magN * magN ) ;
float t8 = P [ 17 ] [ 17 ] * t2 * t6 ;
float t15 = P [ 16 ] [ 17 ] * magE * t6 * t7 ;
float t9 = t8 - t15 ;
float t10 = t2 * t6 * t9 ;
float t11 = P [ 17 ] [ 16 ] * t2 * t6 ;
float t16 = P [ 16 ] [ 16 ] * magE * t6 * t7 ;
float t12 = t11 - t16 ;
float t17 = magE * t6 * t7 * t12 ;
float t13 = R_DECL + t10 - t17 ;
2015-10-19 05:29:11 -03:00
float t14 = 1.0f / t13 ;
2015-10-18 07:16:55 -03:00
float t18 = magE ;
float t19 = magN ;
float t21 = 1.0f / t19 ;
float t22 = t18 * t21 ;
float t20 = tanf ( t22 ) ;
float t23 = t20 * t20 ;
2015-10-19 05:29:11 -03:00
float t24 = t23 + 1.0f ;
2015-10-18 07:16:55 -03:00
float H_MAG [ 24 ] ;
2015-10-19 05:29:11 -03:00
H_MAG [ 16 ] = - t18 * 1.0f / ( t19 * t19 ) * t24 ;
2015-10-18 07:16:55 -03:00
H_MAG [ 17 ] = t21 * t24 ;
for ( uint8_t i = 0 ; i < = 15 ; i + + ) {
Kfusion [ i ] = t14 * ( P [ i ] [ 17 ] * t2 * t6 - P [ i ] [ 16 ] * magE * t6 * t7 ) ;
}
Kfusion [ 16 ] = - t14 * ( t16 - P [ 16 ] [ 17 ] * t2 * t6 ) ;
Kfusion [ 17 ] = t14 * ( t8 - P [ 17 ] [ 16 ] * magE * t6 * t7 ) ;
for ( uint8_t i = 17 ; i < = 23 ; i + + ) {
Kfusion [ i ] = t14 * ( P [ i ] [ 17 ] * t2 * t6 - P [ i ] [ 16 ] * magE * t6 * t7 ) ;
}
// get the magnetic declination
float magDecAng = use_compass ( ) ? _ahrs - > get_compass ( ) - > get_declination ( ) : 0 ;
// Calculate the innovation
float innovation = atanf ( t4 ) - magDecAng ;
// limit the innovation to protect against data errors
if ( innovation > 0.5f ) {
innovation = 0.5f ;
} else if ( innovation < - 0.5f ) {
innovation = - 0.5f ;
}
// zero the attitude error state - by definition it is assumed to be zero before each observaton fusion
stateStruct . angErr . zero ( ) ;
// correct the state vector
for ( uint8_t j = 0 ; j < = stateIndexLim ; j + + ) {
statesArray [ j ] = statesArray [ j ] - Kfusion [ j ] * innovation ;
}
// the first 3 states represent the angular misalignment vector. This is
// is used to correct the estimated quaternion on the current time step
stateStruct . quat . rotate ( stateStruct . angErr ) ;
// correct the covariance P = (I - K*H)*P
// take advantage of the empty columns in KH to reduce the
// number of operations
2015-10-20 00:23:32 -03:00
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = 15 ; j + + ) {
2015-10-18 07:16:55 -03:00
KH [ i ] [ j ] = 0.0f ;
}
2015-10-20 00:23:32 -03:00
KH [ i ] [ 16 ] = Kfusion [ i ] * H_MAG [ 16 ] ;
KH [ i ] [ 17 ] = Kfusion [ i ] * H_MAG [ 17 ] ;
for ( unsigned j = 18 ; j < = 23 ; j + + ) {
2015-10-18 07:16:55 -03:00
KH [ i ] [ j ] = 0.0f ;
}
}
2015-10-20 00:23:32 -03:00
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
KHP [ i ] [ j ] = KH [ i ] [ 16 ] * P [ 16 ] [ j ] + KH [ i ] [ 17 ] * P [ 17 ] [ j ] ;
2015-10-18 07:16:55 -03:00
}
}
2015-10-20 00:23:32 -03:00
for ( unsigned i = 0 ; i < = stateIndexLim ; i + + ) {
for ( unsigned j = 0 ; j < = stateIndexLim ; j + + ) {
2015-10-18 07:16:55 -03:00
P [ i ] [ j ] = P [ i ] [ j ] - KHP [ i ] [ j ] ;
}
}
// force the covariance matrix to be symmetrical and limit the variances to prevent
// ill-condiioning.
ForceSymmetry ( ) ;
ConstrainVariances ( ) ;
}
2015-10-05 23:30:07 -03:00
// Calculate magnetic heading innovation
float NavEKF2_core : : calcMagHeadingInnov ( )
{
// rotate predicted earth components into body axes and calculate
// predicted measurements
Matrix3f Tbn_temp ;
stateStruct . quat . rotation_matrix ( Tbn_temp ) ;
Vector3f magMeasNED = Tbn_temp * magDataDelayed . mag ;
// calculate the innovation where the predicted measurement is the angle wrt magnetic north of the horizontal component of the measured field
float innovation = atan2f ( magMeasNED . y , magMeasNED . x ) - _ahrs - > get_compass ( ) - > get_declination ( ) ;
// wrap the innovation so it sits on the range from +-pi
2015-10-19 18:32:07 -03:00
if ( innovation > M_PI_F ) {
innovation = innovation - 2 * M_PI_F ;
} else if ( innovation < - M_PI_F ) {
innovation = innovation + 2 * M_PI_F ;
2015-10-05 23:30:07 -03:00
}
// Unwrap so that a large yaw gyro bias offset that causes the heading to wrap does not lead to continual uncontrolled heading drift
2015-10-19 18:32:07 -03:00
if ( innovation - lastInnovation > M_PI_F ) {
2015-10-05 23:30:07 -03:00
// Angle has wrapped in the positive direction to subtract an additional 2*Pi
2015-10-19 18:32:07 -03:00
innovationIncrement - = 2 * M_PI_F ;
} else if ( innovation - innovationIncrement < - M_PI_F ) {
2015-10-05 23:30:07 -03:00
// Angle has wrapped in the negative direction so add an additional 2*Pi
2015-10-19 18:32:07 -03:00
innovationIncrement + = 2 * M_PI_F ;
2015-10-05 23:30:07 -03:00
}
lastInnovation = innovation ;
return innovation + innovationIncrement ;
}
/********************************************************
* MISC FUNCTIONS *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// align the NE earth magnetic field states with the published declination
void NavEKF2_core : : alignMagStateDeclination ( )
{
// get the magnetic declination
float magDecAng = use_compass ( ) ? _ahrs - > get_compass ( ) - > get_declination ( ) : 0 ;
// rotate the NE values so that the declination matches the published value
Vector3f initMagNED = stateStruct . earth_magfield ;
float magLengthNE = pythagorous2 ( initMagNED . x , initMagNED . y ) ;
stateStruct . earth_magfield . x = magLengthNE * cosf ( magDecAng ) ;
stateStruct . earth_magfield . y = magLengthNE * sinf ( magDecAng ) ;
}
2015-10-17 20:32:11 -03:00
# endif // HAL_CPU_CLASS