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# include <AP_HAL/AP_HAL.h>
# include "AP_NavEKF3_core.h"
# include <GCS_MAVLink/GCS.h>
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# include <AP_Logger/AP_Logger.h>
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# include <AP_DAL/AP_DAL.h>
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# include <AP_InternalError/AP_InternalError.h>
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/********************************************************
* OPT FLOW AND RANGE FINDER *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// Read the range finder and take new measurements if available
// Apply a median filter
void NavEKF3_core : : readRangeFinder ( void )
{
uint8_t midIndex ;
uint8_t maxIndex ;
uint8_t minIndex ;
// get theoretical correct range when the vehicle is on the ground
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// don't allow range to go below 5cm because this can cause problems with optical flow processing
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const auto * _rng = dal . rangefinder ( ) ;
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if ( _rng = = nullptr ) {
return ;
}
rngOnGnd = MAX ( _rng - > ground_clearance_cm_orient ( ROTATION_PITCH_270 ) * 0.01f , 0.05f ) ;
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// limit update rate to maximum allowed by data buffers
if ( ( imuSampleTime_ms - lastRngMeasTime_ms ) > frontend - > sensorIntervalMin_ms ) {
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// reset the timer used to control the measurement rate
lastRngMeasTime_ms = imuSampleTime_ms ;
// store samples and sample time into a ring buffer if valid
// use data from two range finders if available
for ( uint8_t sensorIndex = 0 ; sensorIndex < = 1 ; sensorIndex + + ) {
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const auto * sensor = _rng - > get_backend ( sensorIndex ) ;
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if ( sensor = = nullptr ) {
continue ;
}
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if ( ( sensor - > orientation ( ) = = ROTATION_PITCH_270 ) & & ( sensor - > status ( ) = = AP_DAL_RangeFinder : : Status : : Good ) ) {
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rngMeasIndex [ sensorIndex ] + + ;
if ( rngMeasIndex [ sensorIndex ] > 2 ) {
rngMeasIndex [ sensorIndex ] = 0 ;
}
storedRngMeasTime_ms [ sensorIndex ] [ rngMeasIndex [ sensorIndex ] ] = imuSampleTime_ms - 25 ;
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storedRngMeas [ sensorIndex ] [ rngMeasIndex [ sensorIndex ] ] = sensor - > distance_cm ( ) * 0.01f ;
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} else {
continue ;
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}
// check for three fresh samples
bool sampleFresh [ 2 ] [ 3 ] = { } ;
for ( uint8_t index = 0 ; index < = 2 ; index + + ) {
sampleFresh [ sensorIndex ] [ index ] = ( imuSampleTime_ms - storedRngMeasTime_ms [ sensorIndex ] [ index ] ) < 500 ;
}
// find the median value if we have three fresh samples
if ( sampleFresh [ sensorIndex ] [ 0 ] & & sampleFresh [ sensorIndex ] [ 1 ] & & sampleFresh [ sensorIndex ] [ 2 ] ) {
if ( storedRngMeas [ sensorIndex ] [ 0 ] > storedRngMeas [ sensorIndex ] [ 1 ] ) {
minIndex = 1 ;
maxIndex = 0 ;
} else {
minIndex = 0 ;
maxIndex = 1 ;
}
if ( storedRngMeas [ sensorIndex ] [ 2 ] > storedRngMeas [ sensorIndex ] [ maxIndex ] ) {
midIndex = maxIndex ;
} else if ( storedRngMeas [ sensorIndex ] [ 2 ] < storedRngMeas [ sensorIndex ] [ minIndex ] ) {
midIndex = minIndex ;
} else {
midIndex = 2 ;
}
// don't allow time to go backwards
if ( storedRngMeasTime_ms [ sensorIndex ] [ midIndex ] > rangeDataNew . time_ms ) {
rangeDataNew . time_ms = storedRngMeasTime_ms [ sensorIndex ] [ midIndex ] ;
}
// limit the measured range to be no less than the on-ground range
rangeDataNew . rng = MAX ( storedRngMeas [ sensorIndex ] [ midIndex ] , rngOnGnd ) ;
// get position in body frame for the current sensor
rangeDataNew . sensor_idx = sensorIndex ;
// write data to buffer with time stamp to be fused when the fusion time horizon catches up with it
storedRange . push ( rangeDataNew ) ;
// indicate we have updated the measurement
rngValidMeaTime_ms = imuSampleTime_ms ;
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} else if ( onGround & & ( ( imuSampleTime_ms - rngValidMeaTime_ms ) > 200 ) ) {
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// before takeoff we assume on-ground range value if there is no data
rangeDataNew . time_ms = imuSampleTime_ms ;
rangeDataNew . rng = rngOnGnd ;
// write data to buffer with time stamp to be fused when the fusion time horizon catches up with it
storedRange . push ( rangeDataNew ) ;
// indicate we have updated the measurement
rngValidMeaTime_ms = imuSampleTime_ms ;
}
}
}
}
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void NavEKF3_core : : writeBodyFrameOdom ( float quality , const Vector3f & delPos , const Vector3f & delAng , float delTime , uint32_t timeStamp_ms , uint16_t delay_ms , const Vector3f & posOffset )
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{
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# if EK3_FEATURE_BODY_ODOM
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// protect against NaN
if ( isnan ( quality ) | | delPos . is_nan ( ) | | delAng . is_nan ( ) | | isnan ( delTime ) | | posOffset . is_nan ( ) ) {
return ;
}
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// limit update rate to maximum allowed by sensor buffers and fusion process
// don't try to write to buffer until the filter has been initialised
if ( ( ( timeStamp_ms - bodyOdmMeasTime_ms ) < frontend - > sensorIntervalMin_ms ) | | ( delTime < dtEkfAvg ) | | ! statesInitialised ) {
return ;
}
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// subtract delay from timestamp
timeStamp_ms - = delay_ms ;
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bodyOdmDataNew . body_offset = posOffset . toftype ( ) ;
bodyOdmDataNew . vel = delPos . toftype ( ) * ( 1.0 / delTime ) ;
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bodyOdmDataNew . time_ms = timeStamp_ms ;
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bodyOdmDataNew . angRate = ( delAng * ( 1.0 / delTime ) ) . toftype ( ) ;
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bodyOdmMeasTime_ms = timeStamp_ms ;
// simple model of accuracy
// TODO move this calculation outside of EKF into the sensor driver
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bodyOdmDataNew . velErr = frontend - > _visOdmVelErrMin + ( frontend - > _visOdmVelErrMax - frontend - > _visOdmVelErrMin ) * ( 1.0f - 0.01f * quality ) ;
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storedBodyOdm . push ( bodyOdmDataNew ) ;
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# endif // EK3_FEATURE_BODY_ODOM
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}
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# if EK3_FEATURE_BODY_ODOM
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void NavEKF3_core : : writeWheelOdom ( float delAng , float delTime , uint32_t timeStamp_ms , const Vector3f & posOffset , float radius )
{
// This is a simple hack to get wheel encoder data into the EKF and verify the interface sign conventions and units
// It uses the exisiting body frame velocity fusion.
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// TODO implement a dedicated wheel odometry observation model
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// rate limiting to 50hz should be done by the caller
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// limit update rate to maximum allowed by sensor buffers and fusion process
// don't try to write to buffer until the filter has been initialised
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if ( ( delTime < dtEkfAvg ) | | ! statesInitialised ) {
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return ;
}
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wheel_odm_elements wheelOdmDataNew = { } ;
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wheelOdmDataNew . hub_offset = posOffset . toftype ( ) ;
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wheelOdmDataNew . delAng = delAng ;
wheelOdmDataNew . radius = radius ;
wheelOdmDataNew . delTime = delTime ;
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// because we are currently converting to an equivalent velocity measurement before fusing
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// the measurement time is moved back to the middle of the sampling period
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wheelOdmDataNew . time_ms = timeStamp_ms - ( uint32_t ) ( 500.0f * delTime ) ;
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storedWheelOdm . push ( wheelOdmDataNew ) ;
}
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# endif // EK3_FEATURE_BODY_ODOM
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// write the raw optical flow measurements
// this needs to be called externally.
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void NavEKF3_core : : writeOptFlowMeas ( const uint8_t rawFlowQuality , const Vector2f & rawFlowRates , const Vector2f & rawGyroRates , const uint32_t msecFlowMeas , const Vector3f & posOffset )
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{
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// limit update rate to maximum allowed by sensor buffers
if ( ( imuSampleTime_ms - flowMeaTime_ms ) < frontend - > sensorIntervalMin_ms ) {
return ;
}
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// The raw measurements need to be optical flow rates in radians/second averaged across the time since the last update
// The PX4Flow sensor outputs flow rates with the following axis and sign conventions:
// A positive X rate is produced by a positive sensor rotation about the X axis
// A positive Y rate is produced by a positive sensor rotation about the Y axis
// This filter uses a different definition of optical flow rates to the sensor with a positive optical flow rate produced by a
// negative rotation about that axis. For example a positive rotation of the flight vehicle about its X (roll) axis would produce a negative X flow rate
flowMeaTime_ms = imuSampleTime_ms ;
// calculate bias errors on flow sensor gyro rates, but protect against spikes in data
// reset the accumulated body delta angle and time
// don't do the calculation if not enough time lapsed for a reliable body rate measurement
if ( delTimeOF > 0.01f ) {
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flowGyroBias . x = 0.99f * flowGyroBias . x + 0.01f * constrain_ftype ( ( rawGyroRates . x - delAngBodyOF . x / delTimeOF ) , - 0.1f , 0.1f ) ;
flowGyroBias . y = 0.99f * flowGyroBias . y + 0.01f * constrain_ftype ( ( rawGyroRates . y - delAngBodyOF . y / delTimeOF ) , - 0.1f , 0.1f ) ;
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delAngBodyOF . zero ( ) ;
delTimeOF = 0.0f ;
}
// by definition if this function is called, then flow measurements have been provided so we
// need to run the optical flow takeoff detection
detectOptFlowTakeoff ( ) ;
// don't use data with a low quality indicator or extreme rates (helps catch corrupt sensor data)
if ( ( rawFlowQuality > 0 ) & & rawFlowRates . length ( ) < 4.2f & & rawGyroRates . length ( ) < 4.2f ) {
// correct flow sensor body rates for bias and write
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of_elements ofDataNew { } ;
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ofDataNew . bodyRadXYZ . x = rawGyroRates . x - flowGyroBias . x ;
ofDataNew . bodyRadXYZ . y = rawGyroRates . y - flowGyroBias . y ;
// the sensor interface doesn't provide a z axis rate so use the rate from the nav sensor instead
if ( delTimeOF > 0.001f ) {
// first preference is to use the rate averaged over the same sampling period as the flow sensor
ofDataNew . bodyRadXYZ . z = delAngBodyOF . z / delTimeOF ;
} else if ( imuDataNew . delAngDT > 0.001f ) {
// second preference is to use most recent IMU data
ofDataNew . bodyRadXYZ . z = imuDataNew . delAng . z / imuDataNew . delAngDT ;
} else {
// third preference is use zero
ofDataNew . bodyRadXYZ . z = 0.0f ;
}
// write uncorrected flow rate measurements
// note correction for different axis and sign conventions used by the px4flow sensor
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ofDataNew . flowRadXY = - rawFlowRates . toftype ( ) ; // raw (non motion compensated) optical flow angular rate about the X axis (rad/sec)
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// write the flow sensor position in body frame
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ofDataNew . body_offset = posOffset . toftype ( ) ;
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// write flow rate measurements corrected for body rates
ofDataNew . flowRadXYcomp . x = ofDataNew . flowRadXY . x + ofDataNew . bodyRadXYZ . x ;
ofDataNew . flowRadXYcomp . y = ofDataNew . flowRadXY . y + ofDataNew . bodyRadXYZ . y ;
// record time last observation was received so we can detect loss of data elsewhere
flowValidMeaTime_ms = imuSampleTime_ms ;
// estimate sample time of the measurement
ofDataNew . time_ms = imuSampleTime_ms - frontend - > _flowDelay_ms - frontend - > flowTimeDeltaAvg_ms / 2 ;
// Correct for the average intersampling delay due to the filter updaterate
ofDataNew . time_ms - = localFilterTimeStep_ms / 2 ;
// Prevent time delay exceeding age of oldest IMU data in the buffer
ofDataNew . time_ms = MAX ( ofDataNew . time_ms , imuDataDelayed . time_ms ) ;
// Save data to buffer
storedOF . push ( ofDataNew ) ;
}
}
/********************************************************
* MAGNETOMETER *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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// try changing compass, return true if a new compass is found
void NavEKF3_core : : tryChangeCompass ( void )
{
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const auto & compass = dal . compass ( ) ;
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const uint8_t maxCount = compass . get_count ( ) ;
// search through the list of magnetometers
for ( uint8_t i = 1 ; i < maxCount ; i + + ) {
uint8_t tempIndex = magSelectIndex + i ;
// loop back to the start index if we have exceeded the bounds
if ( tempIndex > = maxCount ) {
tempIndex - = maxCount ;
}
// if the magnetometer is allowed to be used for yaw and has a different index, we start using it
if ( compass . healthy ( tempIndex ) & & compass . use_for_yaw ( tempIndex ) & & tempIndex ! = magSelectIndex ) {
magSelectIndex = tempIndex ;
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GCS_SEND_TEXT ( MAV_SEVERITY_INFO , " EKF3 IMU%u switching to compass %u " , ( unsigned ) imu_index , magSelectIndex ) ;
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// reset the timeout flag and timer
magTimeout = false ;
lastHealthyMagTime_ms = imuSampleTime_ms ;
// zero the learned magnetometer bias states
stateStruct . body_magfield . zero ( ) ;
// clear the measurement buffer
storedMag . reset ( ) ;
// clear the data waiting flag so that we do not use any data pending from the previous sensor
magDataToFuse = false ;
// request a reset of the magnetic field states
magStateResetRequest = true ;
// declare the field unlearned so that the reset request will be obeyed
magFieldLearned = false ;
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// reset body mag variances on next CovariancePrediction
needMagBodyVarReset = true ;
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return ;
}
}
}
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// check for new magnetometer data and update store measurements if available
void NavEKF3_core : : readMagData ( )
{
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const auto & compass = dal . compass ( ) ;
if ( ! compass . available ( ) ) {
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allMagSensorsFailed = true ;
return ;
}
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// If we are a vehicle with a sideslip constraint to aid yaw estimation and we have timed out on our last avialable
// magnetometer, then declare the magnetometers as failed for this flight
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const uint8_t maxCount = compass . get_count ( ) ;
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if ( allMagSensorsFailed | | ( magTimeout & & assume_zero_sideslip ( ) & & magSelectIndex > = maxCount - 1 & & inFlight ) ) {
allMagSensorsFailed = true ;
return ;
}
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if ( compass . learn_offsets_enabled ( ) ) {
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// while learning offsets keep all mag states reset
InitialiseVariablesMag ( ) ;
wasLearningCompass_ms = imuSampleTime_ms ;
} else if ( wasLearningCompass_ms ! = 0 & & imuSampleTime_ms - wasLearningCompass_ms > 1000 ) {
wasLearningCompass_ms = 0 ;
// force a new yaw alignment 1s after learning completes. The
// delay is to ensure any buffered mag samples are discarded
yawAlignComplete = false ;
InitialiseVariablesMag ( ) ;
}
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// If the magnetometer has timed out (been rejected for too long), we find another magnetometer to use if available
// Don't do this if we are on the ground because there can be magnetic interference and we need to know if there is a problem
// before taking off. Don't do this within the first 30 seconds from startup because the yaw error could be due to large yaw gyro bias affsets
// if the timeout is due to a sensor failure, then declare a timeout regardless of onground status
if ( maxCount > 1 ) {
bool fusionTimeout = magTimeout & & ! onGround & & imuSampleTime_ms - ekfStartTime_ms > 30000 & & ! ( frontend - > _affinity & EKF_AFFINITY_MAG ) ;
bool sensorTimeout = ! compass . healthy ( magSelectIndex ) & & imuSampleTime_ms - lastMagRead_ms > frontend - > magFailTimeLimit_ms ;
if ( fusionTimeout | | sensorTimeout ) {
tryChangeCompass ( ) ;
}
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}
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// limit compass update rate to prevent high processor loading because magnetometer fusion is an expensive step and we could overflow the FIFO buffer
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if ( use_compass ( ) & &
compass . healthy ( magSelectIndex ) & &
( ( compass . last_update_usec ( magSelectIndex ) - lastMagUpdate_us ) > 1000 * frontend - > sensorIntervalMin_ms ) ) {
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// detect changes to magnetometer offset parameters and reset states
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Vector3F nowMagOffsets = compass . get_offsets ( magSelectIndex ) . toftype ( ) ;
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bool changeDetected = lastMagOffsetsValid & & ( nowMagOffsets ! = lastMagOffsets ) ;
if ( changeDetected ) {
// zero the learned magnetometer bias states
stateStruct . body_magfield . zero ( ) ;
// clear the measurement buffer
storedMag . reset ( ) ;
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// reset body mag variances on next
// CovariancePrediction. This copes with possible errors
// in the new offsets
needMagBodyVarReset = true ;
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}
lastMagOffsets = nowMagOffsets ;
lastMagOffsetsValid = true ;
// store time of last measurement update
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lastMagUpdate_us = compass . last_update_usec ( magSelectIndex ) ;
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// Magnetometer data at the current time horizon
mag_elements magDataNew ;
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// estimate of time magnetometer measurement was taken, allowing for delays
magDataNew . time_ms = imuSampleTime_ms - frontend - > magDelay_ms ;
// Correct for the average intersampling delay due to the filter updaterate
magDataNew . time_ms - = localFilterTimeStep_ms / 2 ;
// read compass data and scale to improve numerical conditioning
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magDataNew . mag = ( compass . get_field ( magSelectIndex ) * 0.001f ) . toftype ( ) ;
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// check for consistent data between magnetometers
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consistentMagData = compass . consistent ( ) ;
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// save magnetometer measurement to buffer to be fused later
storedMag . push ( magDataNew ) ;
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// remember time we read compass, to detect compass sensor failure
lastMagRead_ms = imuSampleTime_ms ;
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}
}
/********************************************************
* Inertial Measurements *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/*
* Read IMU delta angle and delta velocity measurements and downsample to 100 Hz
* for storage in the data buffers used by the EKF . If the IMU data arrives at
* lower rate than 100 Hz , then no downsampling or upsampling will be performed .
* Downsampling is done using a method that does not introduce coning or sculling
* errors .
*/
void NavEKF3_core : : readIMUData ( )
{
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const auto & ins = dal . ins ( ) ;
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// calculate an averaged IMU update rate using a spike and lowpass filter combination
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dtIMUavg = 0.02f * constrain_ftype ( ins . get_loop_delta_t ( ) , 0.5f * dtIMUavg , 2.0f * dtIMUavg ) + 0.98f * dtIMUavg ;
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// the imu sample time is used as a common time reference throughout the filter
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imuSampleTime_ms = frontend - > imuSampleTime_us / 1000 ;
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uint8_t accel_active , gyro_active ;
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if ( ins . use_accel ( imu_index ) ) {
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accel_active = imu_index ;
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} else {
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accel_active = ins . get_primary_accel ( ) ;
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}
if ( ins . use_gyro ( imu_index ) ) {
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gyro_active = imu_index ;
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} else {
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gyro_active = ins . get_primary_gyro ( ) ;
}
if ( gyro_active ! = gyro_index_active ) {
// we are switching active gyro at runtime. Copy over the
// bias we have learned from the previously inactive
// gyro. We don't re-init the bias uncertainty as it should
// have the same uncertainty as the previously active gyro
stateStruct . gyro_bias = inactiveBias [ gyro_active ] . gyro_bias ;
gyro_index_active = gyro_active ;
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}
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if ( accel_active ! = accel_index_active ) {
// switch to the learned accel bias for this IMU
stateStruct . accel_bias = inactiveBias [ accel_active ] . accel_bias ;
accel_index_active = accel_active ;
}
// update the inactive bias states
learnInactiveBiases ( ) ;
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// run movement check using IMU data
updateMovementCheck ( ) ;
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readDeltaVelocity ( accel_index_active , imuDataNew . delVel , imuDataNew . delVelDT ) ;
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accelPosOffset = ins . get_imu_pos_offset ( accel_index_active ) . toftype ( ) ;
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imuDataNew . accel_index = accel_index_active ;
// Get delta angle data from primary gyro or primary if not available
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readDeltaAngle ( gyro_index_active , imuDataNew . delAng , imuDataNew . delAngDT ) ;
imuDataNew . delAngDT = MAX ( imuDataNew . delAngDT , 1.0e-4 f ) ;
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imuDataNew . gyro_index = gyro_index_active ;
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// Get current time stamp
imuDataNew . time_ms = imuSampleTime_ms ;
// Accumulate the measurement time interval for the delta velocity and angle data
imuDataDownSampledNew . delAngDT + = imuDataNew . delAngDT ;
imuDataDownSampledNew . delVelDT + = imuDataNew . delVelDT ;
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// use the most recent IMU index for the downsampled IMU
// data. This isn't strictly correct if we switch IMUs between
// samples
imuDataDownSampledNew . gyro_index = imuDataNew . gyro_index ;
imuDataDownSampledNew . accel_index = imuDataNew . accel_index ;
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// Rotate quaternon atitude from previous to new and normalise.
// Accumulation using quaternions prevents introduction of coning errors due to downsampling
imuQuatDownSampleNew . rotate ( imuDataNew . delAng ) ;
imuQuatDownSampleNew . normalize ( ) ;
// Rotate the latest delta velocity into body frame at the start of accumulation
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Matrix3F deltaRotMat ;
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imuQuatDownSampleNew . rotation_matrix ( deltaRotMat ) ;
// Apply the delta velocity to the delta velocity accumulator
imuDataDownSampledNew . delVel + = deltaRotMat * imuDataNew . delVel ;
// Keep track of the number of IMU frames since the last state prediction
framesSincePredict + + ;
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/*
* If the target EKF time step has been accumulated , and the frontend has allowed start of a new predict cycle ,
* then store the accumulated IMU data to be used by the state prediction , ignoring the frontend permission if more
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* than twice the target time has lapsed . Adjust the target EKF step time threshold to allow for timing jitter in the
* IMU data .
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*/
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if ( ( imuDataDownSampledNew . delAngDT > = ( EKF_TARGET_DT - ( dtIMUavg * 0.5f ) ) & & startPredictEnabled ) | |
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( imuDataDownSampledNew . delAngDT > = 2.0f * EKF_TARGET_DT ) ) {
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// convert the accumulated quaternion to an equivalent delta angle
imuQuatDownSampleNew . to_axis_angle ( imuDataDownSampledNew . delAng ) ;
// Time stamp the data
imuDataDownSampledNew . time_ms = imuSampleTime_ms ;
// Write data to the FIFO IMU buffer
storedIMU . push_youngest_element ( imuDataDownSampledNew ) ;
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// calculate the achieved average time step rate for the EKF using a combination spike and LPF
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ftype dtNow = constrain_ftype ( 0.5f * ( imuDataDownSampledNew . delAngDT + imuDataDownSampledNew . delVelDT ) , 0.5f * dtEkfAvg , 2.0f * dtEkfAvg ) ;
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dtEkfAvg = 0.98f * dtEkfAvg + 0.02f * dtNow ;
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// do an addtional down sampling for data used to sample XY body frame drag specific forces
SampleDragData ( imuDataDownSampledNew ) ;
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// zero the accumulated IMU data and quaternion
imuDataDownSampledNew . delAng . zero ( ) ;
imuDataDownSampledNew . delVel . zero ( ) ;
imuDataDownSampledNew . delAngDT = 0.0f ;
imuDataDownSampledNew . delVelDT = 0.0f ;
imuQuatDownSampleNew [ 0 ] = 1.0f ;
imuQuatDownSampleNew [ 3 ] = imuQuatDownSampleNew [ 2 ] = imuQuatDownSampleNew [ 1 ] = 0.0f ;
// reset the counter used to let the frontend know how many frames have elapsed since we started a new update cycle
framesSincePredict = 0 ;
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// set the flag to let the filter know it has new IMU data and needs to run
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runUpdates = true ;
// extract the oldest available data from the FIFO buffer
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imuDataDelayed = storedIMU . get_oldest_element ( ) ;
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// protect against delta time going to zero
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ftype minDT = 0.1f * dtEkfAvg ;
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imuDataDelayed . delAngDT = MAX ( imuDataDelayed . delAngDT , minDT ) ;
imuDataDelayed . delVelDT = MAX ( imuDataDelayed . delVelDT , minDT ) ;
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updateTimingStatistics ( ) ;
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// correct the extracted IMU data for sensor errors
delAngCorrected = imuDataDelayed . delAng ;
delVelCorrected = imuDataDelayed . delVel ;
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correctDeltaAngle ( delAngCorrected , imuDataDelayed . delAngDT , imuDataDelayed . gyro_index ) ;
correctDeltaVelocity ( delVelCorrected , imuDataDelayed . delVelDT , imuDataDelayed . accel_index ) ;
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} else {
// we don't have new IMU data in the buffer so don't run filter updates on this time step
runUpdates = false ;
}
}
// read the delta velocity and corresponding time interval from the IMU
// return false if data is not available
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bool NavEKF3_core : : readDeltaVelocity ( uint8_t ins_index , Vector3F & dVel , ftype & dVel_dt ) {
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const auto & ins = dal . ins ( ) ;
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if ( ins_index < ins . get_accel_count ( ) ) {
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Vector3f dVelF ;
float dVel_dtF ;
ins . get_delta_velocity ( ins_index , dVelF , dVel_dtF ) ;
dVel = dVelF . toftype ( ) ;
dVel_dt = dVel_dtF ;
dVel_dt = MAX ( dVel_dt , 1.0e-4 ) ;
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return true ;
}
return false ;
}
/********************************************************
* Global Position Measurement *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// check for new valid GPS data and update stored measurement if available
void NavEKF3_core : : readGpsData ( )
{
// check for new GPS data
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const auto & gps = dal . gps ( ) ;
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// limit update rate to avoid overflowing the FIFO buffer
if ( gps . last_message_time_ms ( selected_gps ) - lastTimeGpsReceived_ms < = frontend - > sensorIntervalMin_ms ) {
return ;
}
if ( gps . status ( selected_gps ) < AP_DAL_GPS : : GPS_OK_FIX_3D ) {
// report GPS fix status
gpsCheckStatus . bad_fix = true ;
dal . snprintf ( prearm_fail_string , sizeof ( prearm_fail_string ) , " Waiting for 3D fix " ) ;
return ;
}
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// report GPS fix status
gpsCheckStatus . bad_fix = false ;
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// store fix time from previous read
const uint32_t secondLastGpsTime_ms = lastTimeGpsReceived_ms ;
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// get current fix time
lastTimeGpsReceived_ms = gps . last_message_time_ms ( selected_gps ) ;
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// estimate when the GPS fix was valid, allowing for GPS processing and other delays
// ideally we should be using a timing signal from the GPS receiver to set this time
// Use the driver specified delay
float gps_delay_sec = 0 ;
gps . get_lag ( selected_gps , gps_delay_sec ) ;
gpsDataNew . time_ms = lastTimeGpsReceived_ms - ( uint32_t ) ( gps_delay_sec * 1000.0f ) ;
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// Correct for the average intersampling delay due to the filter updaterate
gpsDataNew . time_ms - = localFilterTimeStep_ms / 2 ;
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// Prevent the time stamp falling outside the oldest and newest IMU data in the buffer
gpsDataNew . time_ms = MIN ( MAX ( gpsDataNew . time_ms , imuDataDelayed . time_ms ) , imuDataDownSampledNew . time_ms ) ;
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// Get which GPS we are using for position information
gpsDataNew . sensor_idx = selected_gps ;
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// read the NED velocity from the GPS
gpsDataNew . vel = gps . velocity ( selected_gps ) . toftype ( ) ;
gpsDataNew . have_vz = gps . have_vertical_velocity ( selected_gps ) ;
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// position and velocity are not yet corrected for sensor position
gpsDataNew . corrected = false ;
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// Use the speed and position accuracy from the GPS if available, otherwise set it to zero.
// Apply a decaying envelope filter with a 5 second time constant to the raw accuracy data
ftype alpha = constrain_ftype ( 0.0002f * ( lastTimeGpsReceived_ms - secondLastGpsTime_ms ) , 0.0f , 1.0f ) ;
gpsSpdAccuracy * = ( 1.0f - alpha ) ;
float gpsSpdAccRaw ;
if ( ! gps . speed_accuracy ( selected_gps , gpsSpdAccRaw ) ) {
gpsSpdAccuracy = 0.0f ;
} else {
gpsSpdAccuracy = MAX ( gpsSpdAccuracy , gpsSpdAccRaw ) ;
gpsSpdAccuracy = MIN ( gpsSpdAccuracy , 50.0f ) ;
gpsSpdAccuracy = MAX ( gpsSpdAccuracy , frontend - > _gpsHorizVelNoise ) ;
}
gpsPosAccuracy * = ( 1.0f - alpha ) ;
float gpsPosAccRaw ;
if ( ! gps . horizontal_accuracy ( selected_gps , gpsPosAccRaw ) ) {
gpsPosAccuracy = 0.0f ;
} else {
gpsPosAccuracy = MAX ( gpsPosAccuracy , gpsPosAccRaw ) ;
gpsPosAccuracy = MIN ( gpsPosAccuracy , 100.0f ) ;
gpsPosAccuracy = MAX ( gpsPosAccuracy , frontend - > _gpsHorizPosNoise ) ;
}
gpsHgtAccuracy * = ( 1.0f - alpha ) ;
float gpsHgtAccRaw ;
if ( ! gps . vertical_accuracy ( selected_gps , gpsHgtAccRaw ) ) {
gpsHgtAccuracy = 0.0f ;
} else {
gpsHgtAccuracy = MAX ( gpsHgtAccuracy , gpsHgtAccRaw ) ;
gpsHgtAccuracy = MIN ( gpsHgtAccuracy , 100.0f ) ;
gpsHgtAccuracy = MAX ( gpsHgtAccuracy , 1.5f * frontend - > _gpsHorizPosNoise ) ;
}
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// check if we have enough GPS satellites and increase the gps noise scaler if we don't
if ( gps . num_sats ( selected_gps ) > = 6 & & ( PV_AidingMode = = AID_ABSOLUTE ) ) {
gpsNoiseScaler = 1.0f ;
} else if ( gps . num_sats ( selected_gps ) = = 5 & & ( PV_AidingMode = = AID_ABSOLUTE ) ) {
gpsNoiseScaler = 1.4f ;
} else { // <= 4 satellites or in constant position mode
gpsNoiseScaler = 2.0f ;
}
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// Check if GPS can output vertical velocity, vertical velocity use is permitted and set GPS fusion mode accordingly
if ( gpsDataNew . have_vz & & frontend - > sources . useVelZSource ( AP_NavEKF_Source : : SourceZ : : GPS ) ) {
useGpsVertVel = true ;
} else {
useGpsVertVel = false ;
}
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// Monitor quality of the GPS velocity data before and after alignment
calcGpsGoodToAlign ( ) ;
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// Post-alignment checks
calcGpsGoodForFlight ( ) ;
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// Read the GPS location in WGS-84 lat,long,height coordinates
const struct Location & gpsloc = gps . location ( selected_gps ) ;
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// Set the EKF origin and magnetic field declination if not previously set and GPS checks have passed
if ( gpsGoodToAlign & & ! validOrigin ) {
Location gpsloc_fieldelevation = gpsloc ;
// if flying, correct for height change from takeoff so that the origin is at field elevation
if ( inFlight ) {
gpsloc_fieldelevation . alt + = ( int32_t ) ( 100.0f * stateStruct . position . z ) ;
}
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if ( ! setOrigin ( gpsloc_fieldelevation ) ) {
// set an error as an attempt was made to set the origin more than once
INTERNAL_ERROR ( AP_InternalError : : error_t : : flow_of_control ) ;
return ;
}
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// set the NE earth magnetic field states using the published declination
// and set the corresponding variances and covariances
alignMagStateDeclination ( ) ;
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// Set the height of the NED origin
ekfGpsRefHgt = ( double ) 0.01 * ( double ) gpsloc . alt + ( double ) outputDataNew . position . z ;
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// Set the uncertainty of the GPS origin height
ekfOriginHgtVar = sq ( gpsHgtAccuracy ) ;
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}
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if ( gpsGoodToAlign & & ! have_table_earth_field ) {
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const auto & compass = dal . compass ( ) ;
if ( compass . have_scale_factor ( magSelectIndex ) & &
compass . auto_declination_enabled ( ) ) {
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getEarthFieldTable ( gpsloc ) ;
if ( frontend - > _mag_ef_limit > 0 ) {
// initialise earth field from tables
stateStruct . earth_magfield = table_earth_field_ga ;
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}
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}
}
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// convert GPS measurements to local NED and save to buffer to be fused later if we have a valid origin
if ( validOrigin ) {
gpsDataNew . lat = gpsloc . lat ;
gpsDataNew . lng = gpsloc . lng ;
if ( ( frontend - > _originHgtMode & ( 1 < < 2 ) ) = = 0 ) {
gpsDataNew . hgt = ( ftype ) ( ( double ) 0.01 * ( double ) gpsloc . alt - ekfGpsRefHgt ) ;
} else {
gpsDataNew . hgt = 0.01 * ( gpsloc . alt - EKF_origin . alt ) ;
}
storedGPS . push ( gpsDataNew ) ;
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// declare GPS in use
gpsIsInUse = true ;
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}
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}
// check for new valid GPS yaw data
void NavEKF3_core : : readGpsYawData ( )
{
const auto & gps = dal . gps ( ) ;
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// if the GPS has yaw data then fuse it as an Euler yaw angle
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float yaw_deg , yaw_accuracy_deg ;
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uint32_t yaw_time_ms ;
if ( gps . status ( selected_gps ) > = AP_DAL_GPS : : GPS_OK_FIX_3D & &
dal . gps ( ) . gps_yaw_deg ( selected_gps , yaw_deg , yaw_accuracy_deg , yaw_time_ms ) & &
yaw_time_ms ! = yawMeasTime_ms ) {
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// GPS modules are rather too optimistic about their
// accuracy. Set to min of 5 degrees here to prevent
// the user constantly receiving warnings about high
// normalised yaw innovations
const ftype min_yaw_accuracy_deg = 5.0f ;
yaw_accuracy_deg = MAX ( yaw_accuracy_deg , min_yaw_accuracy_deg ) ;
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writeEulerYawAngle ( radians ( yaw_deg ) , radians ( yaw_accuracy_deg ) , yaw_time_ms , 2 ) ;
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}
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}
// read the delta angle and corresponding time interval from the IMU
// return false if data is not available
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bool NavEKF3_core : : readDeltaAngle ( uint8_t ins_index , Vector3F & dAng , ftype & dAngDT ) {
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const auto & ins = dal . ins ( ) ;
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if ( ins_index < ins . get_gyro_count ( ) ) {
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Vector3f dAngF ;
float dAngDTF ;
ins . get_delta_angle ( ins_index , dAngF , dAngDTF ) ;
dAng = dAngF . toftype ( ) ;
dAngDT = dAngDTF ;
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return true ;
}
return false ;
}
/********************************************************
* Height Measurements *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// check for new pressure altitude measurement data and update stored measurement if available
void NavEKF3_core : : readBaroData ( )
{
// check to see if baro measurement has changed so we know if a new measurement has arrived
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// limit update rate to avoid overflowing the FIFO buffer
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const auto & baro = dal . baro ( ) ;
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if ( baro . get_last_update ( selected_baro ) - lastBaroReceived_ms > frontend - > sensorIntervalMin_ms ) {
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baroDataNew . hgt = baro . get_altitude ( selected_baro ) ;
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// time stamp used to check for new measurement
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lastBaroReceived_ms = baro . get_last_update ( selected_baro ) ;
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// estimate of time height measurement was taken, allowing for delays
baroDataNew . time_ms = lastBaroReceived_ms - frontend - > _hgtDelay_ms ;
// Correct for the average intersampling delay due to the filter updaterate
baroDataNew . time_ms - = localFilterTimeStep_ms / 2 ;
// Prevent time delay exceeding age of oldest IMU data in the buffer
baroDataNew . time_ms = MAX ( baroDataNew . time_ms , imuDataDelayed . time_ms ) ;
// save baro measurement to buffer to be fused later
storedBaro . push ( baroDataNew ) ;
}
}
// calculate filtered offset between baro height measurement and EKF height estimate
// offset should be subtracted from baro measurement to match filter estimate
// offset is used to enable reversion to baro from alternate height data source
void NavEKF3_core : : calcFiltBaroOffset ( )
{
// Apply a first order LPF with spike protection
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baroHgtOffset + = 0.1f * constrain_ftype ( baroDataDelayed . hgt + stateStruct . position . z - baroHgtOffset , - 5.0f , 5.0f ) ;
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}
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// correct the height of the EKF origin to be consistent with GPS Data using a Bayes filter.
void NavEKF3_core : : correctEkfOriginHeight ( )
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{
// Estimate the WGS-84 height of the EKF's origin using a Bayes filter
// calculate the variance of our a-priori estimate of the ekf origin height
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ftype deltaTime = constrain_ftype ( 0.001f * ( imuDataDelayed . time_ms - lastOriginHgtTime_ms ) , 0.0 , 1.0 ) ;
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if ( activeHgtSource = = AP_NavEKF_Source : : SourceZ : : BARO ) {
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// Use the baro drift rate
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const ftype baroDriftRate = 0.05 ;
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ekfOriginHgtVar + = sq ( baroDriftRate * deltaTime ) ;
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} else if ( activeHgtSource = = AP_NavEKF_Source : : SourceZ : : RANGEFINDER ) {
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// use the worse case expected terrain gradient and vehicle horizontal speed
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const ftype maxTerrGrad = 0.25 ;
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ekfOriginHgtVar + = sq ( maxTerrGrad * stateStruct . velocity . xy ( ) . length ( ) * deltaTime ) ;
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} else {
// by definition our height source is absolute so cannot run this filter
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return ;
}
lastOriginHgtTime_ms = imuDataDelayed . time_ms ;
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// calculate the observation variance assuming EKF error relative to datum is independent of GPS observation error
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// when not using GPS as height source
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ftype originHgtObsVar = sq ( gpsHgtAccuracy ) + P [ 9 ] [ 9 ] ;
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// calculate the correction gain
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ftype gain = ekfOriginHgtVar / ( ekfOriginHgtVar + originHgtObsVar ) ;
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// calculate the innovation
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ftype innovation = - stateStruct . position . z - gpsDataDelayed . hgt ;
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// check the innovation variance ratio
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ftype ratio = sq ( innovation ) / ( ekfOriginHgtVar + originHgtObsVar ) ;
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// correct the EKF origin and variance estimate if the innovation is less than 5-sigma
if ( ratio < 25.0f & & gpsAccuracyGood ) {
ekfGpsRefHgt - = ( double ) ( gain * innovation ) ;
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ekfOriginHgtVar - = MAX ( gain * ekfOriginHgtVar , 0.0f ) ;
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}
}
/********************************************************
* Air Speed Measurements *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
// check for new airspeed data and update stored measurements if available
void NavEKF3_core : : readAirSpdData ( )
{
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const float EAS2TAS = dal . get_EAS2TAS ( ) ;
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// if airspeed reading is valid and is set by the user to be used and has been updated then
// we take a new reading, convert from EAS to TAS and set the flag letting other functions
// know a new measurement is available
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const auto * airspeed = dal . airspeed ( ) ;
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if ( airspeed & &
( airspeed - > last_update_ms ( selected_airspeed ) - timeTasReceived_ms ) > frontend - > sensorIntervalMin_ms ) {
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tasDataNew . tas = airspeed - > get_airspeed ( selected_airspeed ) * EAS2TAS ;
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timeTasReceived_ms = airspeed - > last_update_ms ( selected_airspeed ) ;
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tasDataNew . time_ms = timeTasReceived_ms - frontend - > tasDelay_ms ;
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tasDataNew . tasVariance = sq ( MAX ( frontend - > _easNoise * EAS2TAS , 0.5f ) ) ;
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tasDataNew . allowFusion = airspeed - > healthy ( selected_airspeed ) & & airspeed - > use ( selected_airspeed ) ;
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// Correct for the average intersampling delay due to the filter update rate
tasDataNew . time_ms - = localFilterTimeStep_ms / 2 ;
// Save data into the buffer to be fused when the fusion time horizon catches up with it
storedTAS . push ( tasDataNew ) ;
}
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// Check the buffer for measurements that have been overtaken by the fusion time horizon and need to be fused
tasDataToFuse = storedTAS . recall ( tasDataDelayed , imuDataDelayed . time_ms ) ;
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float easErrVar = sq ( MAX ( frontend - > _easNoise , 0.5f ) ) ;
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// Allow use of a default value if enabled
if ( ! useAirspeed ( ) & &
imuDataDelayed . time_ms - tasDataDelayed . time_ms > 200 & &
is_positive ( defaultAirSpeed ) ) {
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tasDataDelayed . tas = defaultAirSpeed * EAS2TAS ;
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tasDataDelayed . tasVariance = sq ( MAX ( defaultAirSpeedVariance , easErrVar ) ) ;
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tasDataDelayed . allowFusion = true ;
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tasDataDelayed . time_ms = 0 ;
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usingDefaultAirspeed = true ;
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} else {
usingDefaultAirspeed = false ;
}
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}
/********************************************************
* Range Beacon Measurements *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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// check for new range beacon data and push to data buffer if available
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void NavEKF3_core : : readRngBcnData ( )
{
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// check that arrays are large enough
static_assert ( ARRAY_SIZE ( lastTimeRngBcn_ms ) > = AP_BEACON_MAX_BEACONS , " lastTimeRngBcn_ms should have at least AP_BEACON_MAX_BEACONS elements " ) ;
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// get the location of the beacon data
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const AP_DAL_Beacon * beacon = dal . beacon ( ) ;
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// exit immediately if no beacon object
if ( beacon = = nullptr ) {
return ;
}
// get the number of beacons in use
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N_beacons = MIN ( beacon - > count ( ) , ARRAY_SIZE ( lastTimeRngBcn_ms ) ) ;
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// search through all the beacons for new data and if we find it stop searching and push the data into the observation buffer
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bool newDataPushed = false ;
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uint8_t numRngBcnsChecked = 0 ;
// start the search one index up from where we left it last time
uint8_t index = lastRngBcnChecked ;
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while ( ! newDataPushed & & ( numRngBcnsChecked < N_beacons ) ) {
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// track the number of beacons checked
numRngBcnsChecked + + ;
// move to next beacon, wrap index if necessary
index + + ;
if ( index > = N_beacons ) {
index = 0 ;
}
// check that the beacon is healthy and has new data
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if ( beacon - > beacon_healthy ( index ) & & beacon - > beacon_last_update_ms ( index ) ! = lastTimeRngBcn_ms [ index ] ) {
rng_bcn_elements rngBcnDataNew = { } ;
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// set the timestamp, correcting for measurement delay and average intersampling delay due to the filter update rate
lastTimeRngBcn_ms [ index ] = beacon - > beacon_last_update_ms ( index ) ;
rngBcnDataNew . time_ms = lastTimeRngBcn_ms [ index ] - frontend - > _rngBcnDelay_ms - localFilterTimeStep_ms / 2 ;
// set the range noise
// TODO the range library should provide the noise/accuracy estimate for each beacon
rngBcnDataNew . rngErr = frontend - > _rngBcnNoise ;
// set the range measurement
rngBcnDataNew . rng = beacon - > beacon_distance ( index ) ;
// set the beacon position
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rngBcnDataNew . beacon_posNED = beacon - > beacon_position ( index ) . toftype ( ) ;
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// identify the beacon identifier
rngBcnDataNew . beacon_ID = index ;
// indicate we have new data to push to the buffer
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newDataPushed = true ;
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// update the last checked index
lastRngBcnChecked = index ;
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// Save data into the buffer to be fused when the fusion time horizon catches up with it
storedRangeBeacon . push ( rngBcnDataNew ) ;
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}
}
// Check if the beacon system has returned a 3D fix
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Vector3f bp ;
float bperr ;
if ( beacon - > get_vehicle_position_ned ( bp , bperr ) ) {
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rngBcnLast3DmeasTime_ms = imuSampleTime_ms ;
}
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beaconVehiclePosNED = bp . toftype ( ) ;
beaconVehiclePosErr = bperr ;
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// Check if the range beacon data can be used to align the vehicle position
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if ( ( imuSampleTime_ms - rngBcnLast3DmeasTime_ms < 250 ) & & ( beaconVehiclePosErr < 1.0f ) & & rngBcnAlignmentCompleted ) {
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// check for consistency between the position reported by the beacon and the position from the 3-State alignment filter
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const ftype posDiffSq = sq ( receiverPos . x - beaconVehiclePosNED . x ) + sq ( receiverPos . y - beaconVehiclePosNED . y ) ;
const ftype posDiffVar = sq ( beaconVehiclePosErr ) + receiverPosCov [ 0 ] [ 0 ] + receiverPosCov [ 1 ] [ 1 ] ;
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if ( posDiffSq < 9.0f * posDiffVar ) {
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rngBcnGoodToAlign = true ;
// Set the EKF origin and magnetic field declination if not previously set
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if ( ! validOrigin & & ( PV_AidingMode ! = AID_ABSOLUTE ) ) {
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// get origin from beacon system
Location origin_loc ;
if ( beacon - > get_origin ( origin_loc ) ) {
setOriginLLH ( origin_loc ) ;
// set the NE earth magnetic field states using the published declination
// and set the corresponding variances and covariances
alignMagStateDeclination ( ) ;
// Set the uncertainty of the origin height
ekfOriginHgtVar = sq ( beaconVehiclePosErr ) ;
}
}
} else {
rngBcnGoodToAlign = false ;
}
} else {
rngBcnGoodToAlign = false ;
}
// Check the buffer for measurements that have been overtaken by the fusion time horizon and need to be fused
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rngBcnDataToFuse = storedRangeBeacon . recall ( rngBcnDataDelayed , imuDataDelayed . time_ms ) ;
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// Correct the range beacon earth frame origin for estimated offset relative to the EKF earth frame origin
if ( rngBcnDataToFuse ) {
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rngBcnDataDelayed . beacon_posNED . x + = bcnPosOffsetNED . x ;
rngBcnDataDelayed . beacon_posNED . y + = bcnPosOffsetNED . y ;
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}
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}
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/********************************************************
* Independant yaw sensor measurements *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
void NavEKF3_core : : writeEulerYawAngle ( float yawAngle , float yawAngleErr , uint32_t timeStamp_ms , uint8_t type )
{
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// limit update rate to maximum allowed by sensor buffers and fusion process
// don't try to write to buffer until the filter has been initialised
if ( ( ( timeStamp_ms - yawMeasTime_ms ) < frontend - > sensorIntervalMin_ms ) | | ! statesInitialised ) {
return ;
}
yawAngDataNew . yawAng = yawAngle ;
yawAngDataNew . yawAngErr = yawAngleErr ;
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if ( type = = 2 ) {
yawAngDataNew . order = rotationOrder : : TAIT_BRYAN_321 ;
} else if ( type = = 1 ) {
yawAngDataNew . order = rotationOrder : : TAIT_BRYAN_312 ;
} else {
return ;
}
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yawAngDataNew . time_ms = timeStamp_ms ;
storedYawAng . push ( yawAngDataNew ) ;
yawMeasTime_ms = timeStamp_ms ;
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}
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// Writes the default equivalent airspeed and 1-sigma uncertainty in m/s to be used in forward flight if a measured airspeed is required and not available.
void NavEKF3_core : : writeDefaultAirSpeed ( float airspeed , float uncertainty )
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{
defaultAirSpeed = airspeed ;
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defaultAirSpeedVariance = sq ( uncertainty ) ;
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}
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/********************************************************
* External Navigation Measurements *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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void NavEKF3_core : : writeExtNavData ( const Vector3f & pos , const Quaternion & quat , float posErr , float angErr , uint32_t timeStamp_ms , uint16_t delay_ms , uint32_t resetTime_ms )
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{
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# if EK3_FEATURE_EXTERNAL_NAV
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// protect against NaN
if ( pos . is_nan ( ) | | isnan ( posErr ) ) {
return ;
}
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// limit update rate to maximum allowed by sensor buffers and fusion process
// don't try to write to buffer until the filter has been initialised
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if ( ( ( timeStamp_ms - extNavMeasTime_ms ) < frontend - > extNavIntervalMin_ms ) | | ! statesInitialised ) {
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return ;
} else {
extNavMeasTime_ms = timeStamp_ms ;
}
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ext_nav_elements extNavDataNew { } ;
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if ( resetTime_ms ! = extNavLastPosResetTime_ms ) {
extNavDataNew . posReset = true ;
extNavLastPosResetTime_ms = resetTime_ms ;
} else {
extNavDataNew . posReset = false ;
}
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extNavDataNew . pos = pos . toftype ( ) ;
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extNavDataNew . posErr = posErr ;
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// calculate timestamp
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timeStamp_ms = timeStamp_ms - delay_ms ;
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// Correct for the average intersampling delay due to the filter update rate
timeStamp_ms - = localFilterTimeStep_ms / 2 ;
// Prevent time delay exceeding age of oldest IMU data in the buffer
timeStamp_ms = MAX ( timeStamp_ms , imuDataDelayed . time_ms ) ;
extNavDataNew . time_ms = timeStamp_ms ;
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// store position data to buffer
storedExtNav . push ( extNavDataNew ) ;
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// protect against attitude or angle being NaN
if ( ! quat . is_nan ( ) & & ! isnan ( angErr ) ) {
// extract yaw from the attitude
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ftype roll_rad , pitch_rad , yaw_rad ;
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quat . to_euler ( roll_rad , pitch_rad , yaw_rad ) ;
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yaw_elements extNavYawAngDataNew ;
extNavYawAngDataNew . yawAng = yaw_rad ;
extNavYawAngDataNew . yawAngErr = MAX ( angErr , radians ( 5.0f ) ) ; // ensure yaw accuracy is no better than 5 degrees (some callers may send zero)
extNavYawAngDataNew . order = rotationOrder : : TAIT_BRYAN_321 ; // Euler rotation order is 321 (ZYX)
extNavYawAngDataNew . time_ms = timeStamp_ms ;
storedExtNavYawAng . push ( extNavYawAngDataNew ) ;
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}
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# endif // EK3_FEATURE_EXTERNAL_NAV
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}
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void NavEKF3_core : : writeExtNavVelData ( const Vector3f & vel , float err , uint32_t timeStamp_ms , uint16_t delay_ms )
{
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# if EK3_FEATURE_EXTERNAL_NAV
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// sanity check for NaNs
if ( vel . is_nan ( ) | | isnan ( err ) ) {
return ;
}
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if ( ( timeStamp_ms - extNavVelMeasTime_ms ) < frontend - > extNavIntervalMin_ms ) {
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return ;
}
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extNavVelMeasTime_ms = timeStamp_ms ;
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useExtNavVel = true ;
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// calculate timestamp
timeStamp_ms = timeStamp_ms - delay_ms ;
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// Correct for the average intersampling delay due to the filter updaterate
timeStamp_ms - = localFilterTimeStep_ms / 2 ;
// Prevent time delay exceeding age of oldest IMU data in the buffer
timeStamp_ms = MAX ( timeStamp_ms , imuDataDelayed . time_ms ) ;
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ext_nav_vel_elements extNavVelNew ;
extNavVelNew . time_ms = timeStamp_ms ;
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extNavVelNew . vel = vel . toftype ( ) ;
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extNavVelNew . err = err ;
extNavVelNew . corrected = false ;
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storedExtNavVel . push ( extNavVelNew ) ;
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# endif // EK3_FEATURE_EXTERNAL_NAV
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}
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/*
update the GPS selection
*/
void NavEKF3_core : : update_gps_selection ( void )
{
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const auto & gps = dal . gps ( ) ;
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// in normal operation use the primary GPS
selected_gps = gps . primary_sensor ( ) ;
preferred_gps = selected_gps ;
if ( frontend - > _affinity & EKF_AFFINITY_GPS ) {
if ( core_index < gps . num_sensors ( ) ) {
// always prefer our core_index, unless we don't have that
// many GPS sensors available
preferred_gps = core_index ;
}
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if ( gps . status ( preferred_gps ) > = AP_DAL_GPS : : GPS_OK_FIX_3D ) {
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// select our preferred_gps if it has a 3D fix, otherwise
// use the primary GPS
selected_gps = preferred_gps ;
}
}
}
/*
update the mag selection
*/
void NavEKF3_core : : update_mag_selection ( void )
{
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const auto & compass = dal . compass ( ) ;
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if ( frontend - > _affinity & EKF_AFFINITY_MAG ) {
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if ( core_index < compass . get_count ( ) & &
compass . healthy ( core_index ) & &
compass . use_for_yaw ( core_index ) ) {
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// use core_index compass if it is healthy
magSelectIndex = core_index ;
}
}
}
/*
update the baro selection
*/
void NavEKF3_core : : update_baro_selection ( void )
{
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auto & baro = dal . baro ( ) ;
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// in normal operation use the primary baro
selected_baro = baro . get_primary ( ) ;
if ( frontend - > _affinity & EKF_AFFINITY_BARO ) {
if ( core_index < baro . num_instances ( ) & &
baro . healthy ( core_index ) ) {
// use core_index baro if it is healthy
selected_baro = core_index ;
}
}
}
/*
update the airspeed selection
*/
void NavEKF3_core : : update_airspeed_selection ( void )
{
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const auto * arsp = dal . airspeed ( ) ;
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if ( arsp = = nullptr ) {
return ;
}
// in normal operation use the primary airspeed sensor
selected_airspeed = arsp - > get_primary ( ) ;
if ( frontend - > _affinity & EKF_AFFINITY_ARSP ) {
if ( core_index < arsp - > get_num_sensors ( ) & &
arsp - > healthy ( core_index ) & &
arsp - > use ( core_index ) ) {
// use core_index airspeed if it is healthy
selected_airspeed = core_index ;
}
}
}
/*
update sensor selections
*/
void NavEKF3_core : : update_sensor_selection ( void )
{
update_gps_selection ( ) ;
update_mag_selection ( ) ;
update_baro_selection ( ) ;
update_airspeed_selection ( ) ;
}
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/*
update timing statistics structure
*/
void NavEKF3_core : : updateTimingStatistics ( void )
{
if ( timing . count = = 0 ) {
timing . dtIMUavg_max = dtIMUavg ;
timing . dtIMUavg_min = dtIMUavg ;
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timing . dtEKFavg_max = dtEkfAvg ;
timing . dtEKFavg_min = dtEkfAvg ;
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timing . delAngDT_max = imuDataDelayed . delAngDT ;
timing . delAngDT_min = imuDataDelayed . delAngDT ;
timing . delVelDT_max = imuDataDelayed . delVelDT ;
timing . delVelDT_min = imuDataDelayed . delVelDT ;
} else {
timing . dtIMUavg_max = MAX ( timing . dtIMUavg_max , dtIMUavg ) ;
timing . dtIMUavg_min = MIN ( timing . dtIMUavg_min , dtIMUavg ) ;
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timing . dtEKFavg_max = MAX ( timing . dtEKFavg_max , dtEkfAvg ) ;
timing . dtEKFavg_min = MIN ( timing . dtEKFavg_min , dtEkfAvg ) ;
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timing . delAngDT_max = MAX ( timing . delAngDT_max , imuDataDelayed . delAngDT ) ;
timing . delAngDT_min = MIN ( timing . delAngDT_min , imuDataDelayed . delAngDT ) ;
timing . delVelDT_max = MAX ( timing . delVelDT_max , imuDataDelayed . delVelDT ) ;
timing . delVelDT_min = MIN ( timing . delVelDT_min , imuDataDelayed . delVelDT ) ;
}
timing . count + + ;
}
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/*
update estimates of inactive bias states . This keeps inactive IMUs
as hot - spares so we can switch to them without causing a jump in the
error
*/
void NavEKF3_core : : learnInactiveBiases ( void )
{
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# if INS_MAX_INSTANCES == 1
inactiveBias [ 0 ] . gyro_bias = stateStruct . gyro_bias ;
inactiveBias [ 0 ] . accel_bias = stateStruct . accel_bias ;
# else
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const auto & ins = dal . ins ( ) ;
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// learn gyro biases
for ( uint8_t i = 0 ; i < INS_MAX_INSTANCES ; i + + ) {
if ( ! ins . use_gyro ( i ) ) {
// can't use this gyro
continue ;
}
if ( gyro_index_active = = i ) {
// use current estimates from main filter of gyro bias
inactiveBias [ i ] . gyro_bias = stateStruct . gyro_bias ;
} else {
// get filtered gyro and use the difference between the
// corrected gyro on the active IMU and the inactive IMU
// to move the inactive bias towards the right value
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Vector3F filtered_gyro_active = ins . get_gyro ( gyro_index_active ) . toftype ( ) - ( stateStruct . gyro_bias / dtEkfAvg ) ;
Vector3F filtered_gyro_inactive = ins . get_gyro ( i ) . toftype ( ) - ( inactiveBias [ i ] . gyro_bias / dtEkfAvg ) ;
Vector3F error = filtered_gyro_active - filtered_gyro_inactive ;
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// prevent a single large error from contaminating bias estimate
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const ftype bias_limit = radians ( 5 ) ;
error . x = constrain_ftype ( error . x , - bias_limit , bias_limit ) ;
error . y = constrain_ftype ( error . y , - bias_limit , bias_limit ) ;
error . z = constrain_ftype ( error . z , - bias_limit , bias_limit ) ;
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// slowly bring the inactive gyro in line with the active gyro. This corrects a 5 deg/sec
// gyro bias error in around 1 minute
inactiveBias [ i ] . gyro_bias - = error * ( 1.0e-4 f * dtEkfAvg ) ;
}
}
// learn accel biases
for ( uint8_t i = 0 ; i < INS_MAX_INSTANCES ; i + + ) {
if ( ! ins . use_accel ( i ) ) {
// can't use this accel
continue ;
}
if ( accel_index_active = = i ) {
// use current estimates from main filter of accel bias
inactiveBias [ i ] . accel_bias = stateStruct . accel_bias ;
} else {
// get filtered accel and use the difference between the
// corrected accel on the active IMU and the inactive IMU
// to move the inactive bias towards the right value
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Vector3F filtered_accel_active = ins . get_accel ( accel_index_active ) . toftype ( ) - ( stateStruct . accel_bias / dtEkfAvg ) ;
Vector3F filtered_accel_inactive = ins . get_accel ( i ) . toftype ( ) - ( inactiveBias [ i ] . accel_bias / dtEkfAvg ) ;
Vector3F error = filtered_accel_active - filtered_accel_inactive ;
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// prevent a single large error from contaminating bias estimate
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const ftype bias_limit = 1.0 ; // m/s/s
error . x = constrain_ftype ( error . x , - bias_limit , bias_limit ) ;
error . y = constrain_ftype ( error . y , - bias_limit , bias_limit ) ;
error . z = constrain_ftype ( error . z , - bias_limit , bias_limit ) ;
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// slowly bring the inactive accel in line with the active
// accel. This corrects a 0.5 m/s/s accel bias error in
// around 1 minute
inactiveBias [ i ] . accel_bias - = error * ( 1.0e-4 f * dtEkfAvg ) ;
}
}
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# endif
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}
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/*
return declination in radians
*/
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ftype NavEKF3_core : : MagDeclination ( void ) const
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{
// if we are using the WMM tables then use the table declination
// to ensure consistency with the table mag field. Otherwise use
// the declination from the compass library
if ( have_table_earth_field & & frontend - > _mag_ef_limit > 0 ) {
return table_declination ;
}
if ( ! use_compass ( ) ) {
return 0 ;
}
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return dal . compass ( ) . get_declination ( ) ;
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}
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/*
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Update the on ground and not moving check .
Should be called once per IMU update .
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Only updates when on ground and when operating without a magnetometer
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*/
void NavEKF3_core : : updateMovementCheck ( void )
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{
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const AP_NavEKF_Source : : SourceYaw yaw_source = frontend - > sources . getYawSource ( ) ;
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const bool runCheck = onGround & & ( yaw_source = = AP_NavEKF_Source : : SourceYaw : : GPS | | yaw_source = = AP_NavEKF_Source : : SourceYaw : : GPS_COMPASS_FALLBACK | |
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yaw_source = = AP_NavEKF_Source : : SourceYaw : : EXTNAV | | yaw_source = = AP_NavEKF_Source : : SourceYaw : : GSF | | ! use_compass ( ) ) ;
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if ( ! runCheck )
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{
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onGroundNotMoving = false ;
return ;
}
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const ftype gyro_limit = radians ( 3.0f ) ;
const ftype gyro_diff_limit = 0.2f ;
const ftype accel_limit = 1.0f ;
const ftype accel_diff_limit = 5.0f ;
const ftype hysteresis_ratio = 0.7f ;
const ftype dtEkfAvgInv = 1.0f / dtEkfAvg ;
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// get latest bias corrected gyro and accelerometer data
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const auto & ins = dal . ins ( ) ;
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Vector3F gyro = ins . get_gyro ( gyro_index_active ) . toftype ( ) - stateStruct . gyro_bias * dtEkfAvgInv ;
Vector3F accel = ins . get_accel ( accel_index_active ) . toftype ( ) - stateStruct . accel_bias * dtEkfAvgInv ;
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if ( ! prevOnGround ) {
gyro_prev = gyro ;
accel_prev = accel ;
onGroundNotMoving = false ;
gyro_diff = gyro_diff_limit ;
accel_diff = accel_diff_limit ;
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return ;
}
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// calculate a gyro rate of change metric
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Vector3F temp = ( gyro - gyro_prev ) * dtEkfAvgInv ;
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gyro_prev = gyro ;
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gyro_diff = 0.99f * gyro_diff + 0.01f * temp . length ( ) ;
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// calculate a acceleration rate of change metric
temp = ( accel - accel_prev ) * dtEkfAvgInv ;
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accel_prev = accel ;
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accel_diff = 0.99f * accel_diff + 0.01f * temp . length ( ) ;
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const ftype gyro_length_ratio = gyro . length ( ) / gyro_limit ;
const ftype accel_length_ratio = ( accel . length ( ) - GRAVITY_MSS ) / accel_limit ;
const ftype gyro_diff_ratio = gyro_diff / gyro_diff_limit ;
const ftype accel_diff_ratio = accel_diff / accel_diff_limit ;
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bool logStatusChange = false ;
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if ( onGroundNotMoving ) {
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if ( gyro_length_ratio > frontend - > _ognmTestScaleFactor | |
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fabsF ( accel_length_ratio ) > frontend - > _ognmTestScaleFactor | |
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gyro_diff_ratio > frontend - > _ognmTestScaleFactor | |
accel_diff_ratio > frontend - > _ognmTestScaleFactor )
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{
onGroundNotMoving = false ;
logStatusChange = true ;
}
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} else if ( gyro_length_ratio < frontend - > _ognmTestScaleFactor * hysteresis_ratio & &
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fabsF ( accel_length_ratio ) < frontend - > _ognmTestScaleFactor * hysteresis_ratio & &
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gyro_diff_ratio < frontend - > _ognmTestScaleFactor * hysteresis_ratio & &
accel_diff_ratio < frontend - > _ognmTestScaleFactor * hysteresis_ratio )
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{
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onGroundNotMoving = true ;
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logStatusChange = true ;
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}
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if ( logStatusChange | | imuSampleTime_ms - lastMoveCheckLogTime_ms > 200 ) {
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lastMoveCheckLogTime_ms = imuSampleTime_ms ;
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const struct log_XKFM pkt {
LOG_PACKET_HEADER_INIT ( LOG_XKFM_MSG ) ,
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time_us : dal . micros64 ( ) ,
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core : core_index ,
ongroundnotmoving : onGroundNotMoving ,
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gyro_length_ratio : float ( gyro_length_ratio ) ,
accel_length_ratio : float ( accel_length_ratio ) ,
gyro_diff_ratio : float ( gyro_diff_ratio ) ,
accel_diff_ratio : float ( accel_diff_ratio ) ,
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} ;
AP : : logger ( ) . WriteBlock ( & pkt , sizeof ( pkt ) ) ;
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}
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}
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void NavEKF3_core : : SampleDragData ( const imu_elements & imu )
{
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# if EK3_FEATURE_DRAG_FUSION
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// Average and down sample to 5Hz
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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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if ( ! using_bcoef_x & & ! using_bcoef_y & & ! using_mcoef ) {
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// nothing to do
dragFusionEnabled = false ;
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return ;
}
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dragFusionEnabled = true ;
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// down-sample the drag specific force data by accumulating and calculating the mean when
// sufficient samples have been collected
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dragSampleCount + + ;
// note acceleration is accumulated as a delta velocity
dragDownSampled . accelXY . x + = imu . delVel . x ;
dragDownSampled . accelXY . y + = imu . delVel . y ;
dragDownSampled . time_ms + = imu . time_ms ;
dragSampleTimeDelta + = imu . delVelDT ;
// calculate and store means from accumulated values
if ( dragSampleTimeDelta > 0.2f - 0.5f * EKF_TARGET_DT ) {
// note conversion from accumulated delta velocity to acceleration
dragDownSampled . accelXY . x / = dragSampleTimeDelta ;
dragDownSampled . accelXY . y / = dragSampleTimeDelta ;
dragDownSampled . time_ms / = dragSampleCount ;
// write to buffer
storedDrag . push ( dragDownSampled ) ;
// reset accumulators
dragSampleCount = 0 ;
dragDownSampled . accelXY . zero ( ) ;
dragDownSampled . time_ms = 0 ;
dragSampleTimeDelta = 0.0f ;
}
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# endif // EK3_FEATURE_DRAG_FUSION
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}
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/*
get the earth mag field
*/
void NavEKF3_core : : getEarthFieldTable ( const Location & loc )
{
table_earth_field_ga = AP_Declination : : get_earth_field_ga ( loc ) . toftype ( ) ;
table_declination = radians ( AP_Declination : : get_declination ( loc . lat * 1.0e-7 ,
loc . lng * 1.0e-7 ) ) ;
have_table_earth_field = true ;
}
/*
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update earth field , called at 1 Hz
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*/
void NavEKF3_core : : checkUpdateEarthField ( void )
{
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if ( have_table_earth_field & & filterStatus . flags . using_gps ) {
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Location loc = EKF_origin ;
loc . offset ( stateStruct . position . x , stateStruct . position . y ) ;
getEarthFieldTable ( loc ) ;
}
}