mirror of https://github.com/ArduPilot/ardupilot
788 lines
37 KiB
C++
788 lines
37 KiB
C++
#include <AP_HAL/AP_HAL.h>
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#include "AP_NavEKF3.h"
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#include "AP_NavEKF3_core.h"
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#if EK3_FEATURE_OPTFLOW_FUSION
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#include <GCS_MAVLink/GCS.h>
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#include <AP_DAL/AP_DAL.h>
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/********************************************************
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* RESET FUNCTIONS *
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********************************************************/
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/********************************************************
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* FUSE MEASURED_DATA *
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********************************************************/
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// select fusion of optical flow measurements
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void NavEKF3_core::SelectFlowFusion()
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{
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// Check if the magnetometer has been fused on that time step and the filter is running at faster than 200 Hz
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// If so, don't fuse measurements on this time step to reduce frame over-runs
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// Only allow one time slip to prevent high rate magnetometer data preventing fusion of other measurements
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if (magFusePerformed && dtIMUavg < 0.005f && !optFlowFusionDelayed) {
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optFlowFusionDelayed = true;
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return;
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} else {
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optFlowFusionDelayed = false;
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}
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of_elements ofDataDelayed; // OF data at the fusion time horizon
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// Check for data at the fusion time horizon
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const bool flowDataToFuse = storedOF.recall(ofDataDelayed, imuDataDelayed.time_ms);
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// Perform Data Checks
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// Check if the optical flow data is still valid
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flowDataValid = ((imuSampleTime_ms - flowValidMeaTime_ms) < 1000);
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// check is the terrain offset estimate is still valid - if we are using range finder as the main height reference, the ground is assumed to be at 0
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gndOffsetValid = ((imuSampleTime_ms - gndHgtValidTime_ms) < 5000) || (activeHgtSource == AP_NavEKF_Source::SourceZ::RANGEFINDER);
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// Perform tilt check
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bool tiltOK = (prevTnb.c.z > frontend->DCM33FlowMin);
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// Constrain measurements to zero if takeoff is not detected and the height above ground
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// is insufficient to achieve acceptable focus. This allows the vehicle to be picked up
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// and carried to test optical flow operation
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if (!takeOffDetected && ((terrainState - stateStruct.position.z) < 0.5f)) {
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ofDataDelayed.flowRadXYcomp.zero();
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ofDataDelayed.flowRadXY.zero();
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flowDataValid = true;
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}
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// if have valid flow or range measurements, fuse data into a 1-state EKF to estimate terrain height
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if (((flowDataToFuse && (frontend->_flowUse == FLOW_USE_TERRAIN)) || rangeDataToFuse) && tiltOK) {
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// Estimate the terrain offset (runs a one state EKF)
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EstimateTerrainOffset(ofDataDelayed);
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}
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// Fuse optical flow data into the main filter
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if (flowDataToFuse && tiltOK) {
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const bool fuse_optflow = (frontend->_flowUse == FLOW_USE_NAV) && frontend->sources.useVelXYSource(AP_NavEKF_Source::SourceXY::OPTFLOW);
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// Set the flow noise used by the fusion processes
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R_LOS = sq(MAX(frontend->_flowNoise, 0.05f));
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// Fuse the optical flow X and Y axis data into the main filter sequentially
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FuseOptFlow(ofDataDelayed, fuse_optflow);
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}
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}
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/*
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Estimation of terrain offset using a single state EKF
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The filter can fuse motion compensated optical flow rates and range finder measurements
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Equations generated using https://github.com/PX4/ecl/tree/master/EKF/matlab/scripts/Terrain%20Estimator
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*/
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void NavEKF3_core::EstimateTerrainOffset(const of_elements &ofDataDelayed)
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{
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// horizontal velocity squared
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ftype velHorizSq = sq(stateStruct.velocity.x) + sq(stateStruct.velocity.y);
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// don't fuse flow data if LOS rate is misaligned, without GPS, or insufficient velocity, as it is poorly observable
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// don't fuse flow data if it exceeds validity limits
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// don't update terrain offset if ground is being used as the zero height datum in the main filter
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bool cantFuseFlowData = ((frontend->_flowUse != FLOW_USE_TERRAIN)
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|| !gpsIsInUse
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|| PV_AidingMode == AID_RELATIVE
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|| velHorizSq < 25.0f
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|| (MAX(ofDataDelayed.flowRadXY[0],ofDataDelayed.flowRadXY[1]) > frontend->_maxFlowRate));
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if ((!rangeDataToFuse && cantFuseFlowData) || (activeHgtSource == AP_NavEKF_Source::SourceZ::RANGEFINDER)) {
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// skip update
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inhibitGndState = true;
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} else {
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inhibitGndState = false;
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// propagate ground position state noise each time this is called using the difference in position since the last observations and an RMS gradient assumption
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// limit distance to prevent intialisation after bad gps causing bad numerical conditioning
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ftype distanceTravelledSq = sq(stateStruct.position[0] - prevPosN) + sq(stateStruct.position[1] - prevPosE);
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distanceTravelledSq = MIN(distanceTravelledSq, 100.0f);
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prevPosN = stateStruct.position[0];
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prevPosE = stateStruct.position[1];
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// in addition to a terrain gradient error model, we also have the growth in uncertainty due to the copter's vertical velocity
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ftype timeLapsed = MIN(0.001f * (imuSampleTime_ms - timeAtLastAuxEKF_ms), 1.0f);
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ftype Pincrement = (distanceTravelledSq * sq(frontend->_terrGradMax)) + sq(timeLapsed)*P[6][6];
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Popt += Pincrement;
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timeAtLastAuxEKF_ms = imuSampleTime_ms;
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// fuse range finder data
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if (rangeDataToFuse) {
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// reset terrain state if rangefinder data not fused for 5 seconds
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if (imuSampleTime_ms - gndHgtValidTime_ms > 5000) {
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terrainState = MAX(rangeDataDelayed.rng * prevTnb.c.z, rngOnGnd) + stateStruct.position.z;
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}
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// predict range
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ftype predRngMeas = MAX((terrainState - stateStruct.position[2]),rngOnGnd) / prevTnb.c.z;
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// Copy required states to local variable names
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ftype q0 = stateStruct.quat[0]; // quaternion at optical flow measurement time
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ftype q1 = stateStruct.quat[1]; // quaternion at optical flow measurement time
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ftype q2 = stateStruct.quat[2]; // quaternion at optical flow measurement time
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ftype q3 = stateStruct.quat[3]; // quaternion at optical flow measurement time
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// Set range finder measurement noise variance. TODO make this a function of range and tilt to allow for sensor, alignment and AHRS errors
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ftype R_RNG = frontend->_rngNoise;
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// calculate Kalman gain
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ftype SK_RNG = sq(q0) - sq(q1) - sq(q2) + sq(q3);
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ftype K_RNG = Popt/(SK_RNG*(R_RNG + Popt/sq(SK_RNG)));
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// Calculate the innovation variance for data logging
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varInnovRng = (R_RNG + Popt/sq(SK_RNG));
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// constrain terrain height to be below the vehicle
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terrainState = MAX(terrainState, stateStruct.position[2] + rngOnGnd);
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// Calculate the measurement innovation
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innovRng = predRngMeas - rangeDataDelayed.rng;
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// calculate the innovation consistency test ratio
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auxRngTestRatio = sq(innovRng) / (sq(MAX(0.01f * (ftype)frontend->_rngInnovGate, 1.0f)) * varInnovRng);
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// Check the innovation test ratio and don't fuse if too large
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if (auxRngTestRatio < 1.0f) {
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// correct the state
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terrainState -= K_RNG * innovRng;
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// constrain the state
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terrainState = MAX(terrainState, stateStruct.position[2] + rngOnGnd);
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// correct the covariance
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Popt = Popt - sq(Popt)/(SK_RNG*(R_RNG + Popt/sq(SK_RNG))*(sq(q0) - sq(q1) - sq(q2) + sq(q3)));
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// prevent the state variance from becoming negative
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Popt = MAX(Popt,0.0f);
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// record the time we last updated the terrain offset state
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gndHgtValidTime_ms = imuSampleTime_ms;
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}
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}
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if (!cantFuseFlowData) {
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Vector3F relVelSensor; // velocity of sensor relative to ground in sensor axes
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Vector2F losPred; // predicted optical flow angular rate measurement
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ftype q0 = stateStruct.quat[0]; // quaternion at optical flow measurement time
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ftype q1 = stateStruct.quat[1]; // quaternion at optical flow measurement time
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ftype q2 = stateStruct.quat[2]; // quaternion at optical flow measurement time
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ftype q3 = stateStruct.quat[3]; // quaternion at optical flow measurement time
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ftype K_OPT;
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ftype H_OPT;
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Vector2F auxFlowObsInnovVar;
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// predict range to centre of image
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ftype flowRngPred = MAX((terrainState - stateStruct.position.z),rngOnGnd) / prevTnb.c.z;
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// constrain terrain height to be below the vehicle
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terrainState = MAX(terrainState, stateStruct.position.z + rngOnGnd);
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// calculate relative velocity in sensor frame
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relVelSensor = prevTnb*stateStruct.velocity;
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// divide velocity by range, subtract body rates and apply scale factor to
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// get predicted sensed angular optical rates relative to X and Y sensor axes
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losPred.x = relVelSensor.y / flowRngPred;
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losPred.y = - relVelSensor.x / flowRngPred;
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// calculate innovations
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auxFlowObsInnov = losPred - ofDataDelayed.flowRadXYcomp;
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// calculate observation jacobians
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ftype t2 = q0*q0;
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ftype t3 = q1*q1;
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ftype t4 = q2*q2;
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ftype t5 = q3*q3;
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ftype t6 = stateStruct.position.z - terrainState;
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ftype t7 = 1.0f / (t6*t6);
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ftype t8 = q0*q3*2.0f;
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ftype t9 = t2-t3-t4+t5;
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// prevent the state variances from becoming badly conditioned
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Popt = MAX(Popt,1E-6f);
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// calculate observation noise variance from parameter
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ftype flow_noise_variance = sq(MAX(frontend->_flowNoise, 0.05f));
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// Fuse Y axis data
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// Calculate observation partial derivative
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H_OPT = t7*t9*(-stateStruct.velocity.z*(q0*q2*2.0-q1*q3*2.0)+stateStruct.velocity.x*(t2+t3-t4-t5)+stateStruct.velocity.y*(t8+q1*q2*2.0));
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// calculate innovation variance
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auxFlowObsInnovVar.y = H_OPT * Popt * H_OPT + flow_noise_variance;
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// calculate Kalman gain
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K_OPT = Popt * H_OPT / auxFlowObsInnovVar.y;
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// calculate the innovation consistency test ratio
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auxFlowTestRatio.y = sq(auxFlowObsInnov.y) / (sq(MAX(0.01f * (ftype)frontend->_flowInnovGate, 1.0f)) * auxFlowObsInnovVar.y);
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// don't fuse if optical flow data is outside valid range
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if (auxFlowTestRatio.y < 1.0f) {
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// correct the state
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terrainState -= K_OPT * auxFlowObsInnov.y;
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// constrain the state
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terrainState = MAX(terrainState, stateStruct.position.z + rngOnGnd);
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// update intermediate variables used when fusing the X axis
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t6 = stateStruct.position.z - terrainState;
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t7 = 1.0f / (t6*t6);
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// correct the covariance
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Popt = Popt - K_OPT * H_OPT * Popt;
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// prevent the state variances from becoming badly conditioned
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Popt = MAX(Popt,1E-6f);
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// record the time we last updated the terrain offset state
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gndHgtValidTime_ms = imuSampleTime_ms;
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}
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// fuse X axis data
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H_OPT = -t7*t9*(stateStruct.velocity.z*(q0*q1*2.0+q2*q3*2.0)+stateStruct.velocity.y*(t2-t3+t4-t5)-stateStruct.velocity.x*(t8-q1*q2*2.0));
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// calculate innovation variances
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auxFlowObsInnovVar.x = H_OPT * Popt * H_OPT + flow_noise_variance;
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// calculate Kalman gain
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K_OPT = Popt * H_OPT / auxFlowObsInnovVar.x;
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// calculate the innovation consistency test ratio
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auxFlowTestRatio.x = sq(auxFlowObsInnov.x) / (sq(MAX(0.01f * (ftype)frontend->_flowInnovGate, 1.0f)) * auxFlowObsInnovVar.x);
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// don't fuse if optical flow data is outside valid range
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if (auxFlowTestRatio.x < 1.0f) {
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// correct the state
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terrainState -= K_OPT * auxFlowObsInnov.x;
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// constrain the state
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terrainState = MAX(terrainState, stateStruct.position.z + rngOnGnd);
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// correct the covariance
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Popt = Popt - K_OPT * H_OPT * Popt;
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// prevent the state variances from becoming badly conditioned
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Popt = MAX(Popt,1E-6f);
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}
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}
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}
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}
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/*
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* Fuse angular motion compensated optical flow rates using explicit algebraic equations generated with Matlab symbolic toolbox.
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* The script file used to generate these and other equations in this filter can be found here:
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* https://github.com/PX4/ecl/blob/master/matlab/scripts/Inertial%20Nav%20EKF/GenerateNavFilterEquations.m
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* Requires a valid terrain height estimate.
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*
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* really_fuse should be true to actually fuse into the main filter, false to only calculate variances
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*/
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void NavEKF3_core::FuseOptFlow(const of_elements &ofDataDelayed, bool really_fuse)
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{
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Vector24 H_LOS;
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Vector2 losPred;
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// Copy required states to local variable names
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ftype q0 = stateStruct.quat[0];
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ftype q1 = stateStruct.quat[1];
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ftype q2 = stateStruct.quat[2];
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ftype q3 = stateStruct.quat[3];
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ftype vn = stateStruct.velocity.x;
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ftype ve = stateStruct.velocity.y;
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ftype vd = stateStruct.velocity.z;
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ftype pd = stateStruct.position.z;
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// constrain height above ground to be above range measured on ground
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ftype heightAboveGndEst = MAX((terrainState - pd), rngOnGnd);
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// calculate range from ground plain to centre of sensor fov assuming flat earth
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ftype range = constrain_ftype((heightAboveGndEst/prevTnb.c.z),rngOnGnd,1000.0f);
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// correct range for flow sensor offset body frame position offset
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// the corrected value is the predicted range from the sensor focal point to the
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// centre of the image on the ground assuming flat terrain
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Vector3F posOffsetBody = ofDataDelayed.body_offset - accelPosOffset;
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if (!posOffsetBody.is_zero()) {
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Vector3F posOffsetEarth = prevTnb.mul_transpose(posOffsetBody);
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range -= posOffsetEarth.z / prevTnb.c.z;
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}
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#if APM_BUILD_TYPE(APM_BUILD_Rover)
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// override with user specified height (if given, for rover)
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if (ofDataDelayed.heightOverride > 0) {
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range = ofDataDelayed.heightOverride;
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}
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#endif
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// Fuse X and Y axis measurements sequentially assuming observation errors are uncorrelated
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for (uint8_t obsIndex=0; obsIndex<=1; obsIndex++) { // fuse X axis data first
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// calculate relative velocity in sensor frame including the relative motion due to rotation
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const Vector3F relVelSensor = (prevTnb * stateStruct.velocity) + (ofDataDelayed.bodyRadXYZ % posOffsetBody);
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// divide velocity by range to get predicted angular LOS rates relative to X and Y axes
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losPred[0] = relVelSensor.y/range;
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losPred[1] = -relVelSensor.x/range;
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// calculate observation jacobians and Kalman gains
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memset(&H_LOS[0], 0, sizeof(H_LOS));
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if (obsIndex == 0) {
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// calculate X axis observation Jacobian
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ftype t2 = 1.0f / range;
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H_LOS[0] = t2*(q1*vd*2.0f+q0*ve*2.0f-q3*vn*2.0f);
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H_LOS[1] = t2*(q0*vd*2.0f-q1*ve*2.0f+q2*vn*2.0f);
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H_LOS[2] = t2*(q3*vd*2.0f+q2*ve*2.0f+q1*vn*2.0f);
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H_LOS[3] = -t2*(q2*vd*-2.0f+q3*ve*2.0f+q0*vn*2.0f);
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H_LOS[4] = -t2*(q0*q3*2.0f-q1*q2*2.0f);
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H_LOS[5] = t2*(q0*q0-q1*q1+q2*q2-q3*q3);
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H_LOS[6] = t2*(q0*q1*2.0f+q2*q3*2.0f);
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// calculate intermediate variables for the X observation innovation variance and Kalman gains
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ftype t3 = q1*vd*2.0f;
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ftype t4 = q0*ve*2.0f;
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ftype t11 = q3*vn*2.0f;
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ftype t5 = t3+t4-t11;
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ftype t6 = q0*q3*2.0f;
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ftype t29 = q1*q2*2.0f;
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ftype t7 = t6-t29;
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ftype t8 = q0*q1*2.0f;
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ftype t9 = q2*q3*2.0f;
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ftype t10 = t8+t9;
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ftype t12 = P[0][0]*t2*t5;
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ftype t13 = q0*vd*2.0f;
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ftype t14 = q2*vn*2.0f;
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ftype t28 = q1*ve*2.0f;
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ftype t15 = t13+t14-t28;
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ftype t16 = q3*vd*2.0f;
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ftype t17 = q2*ve*2.0f;
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ftype t18 = q1*vn*2.0f;
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ftype t19 = t16+t17+t18;
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ftype t20 = q3*ve*2.0f;
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ftype t21 = q0*vn*2.0f;
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ftype t30 = q2*vd*2.0f;
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ftype t22 = t20+t21-t30;
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ftype t23 = q0*q0;
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ftype t24 = q1*q1;
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ftype t25 = q2*q2;
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ftype t26 = q3*q3;
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ftype t27 = t23-t24+t25-t26;
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ftype t31 = P[1][1]*t2*t15;
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ftype t32 = P[6][0]*t2*t10;
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ftype t33 = P[1][0]*t2*t15;
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ftype t34 = P[2][0]*t2*t19;
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ftype t35 = P[5][0]*t2*t27;
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ftype t79 = P[4][0]*t2*t7;
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ftype t80 = P[3][0]*t2*t22;
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ftype t36 = t12+t32+t33+t34+t35-t79-t80;
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ftype t37 = t2*t5*t36;
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ftype t38 = P[6][1]*t2*t10;
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ftype t39 = P[0][1]*t2*t5;
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ftype t40 = P[2][1]*t2*t19;
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ftype t41 = P[5][1]*t2*t27;
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ftype t81 = P[4][1]*t2*t7;
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ftype t82 = P[3][1]*t2*t22;
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ftype t42 = t31+t38+t39+t40+t41-t81-t82;
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ftype t43 = t2*t15*t42;
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ftype t44 = P[6][2]*t2*t10;
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ftype t45 = P[0][2]*t2*t5;
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ftype t46 = P[1][2]*t2*t15;
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ftype t47 = P[2][2]*t2*t19;
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ftype t48 = P[5][2]*t2*t27;
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ftype t83 = P[4][2]*t2*t7;
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ftype t84 = P[3][2]*t2*t22;
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ftype t49 = t44+t45+t46+t47+t48-t83-t84;
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ftype t50 = t2*t19*t49;
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ftype t51 = P[6][3]*t2*t10;
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ftype t52 = P[0][3]*t2*t5;
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ftype t53 = P[1][3]*t2*t15;
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ftype t54 = P[2][3]*t2*t19;
|
|
ftype t55 = P[5][3]*t2*t27;
|
|
ftype t85 = P[4][3]*t2*t7;
|
|
ftype t86 = P[3][3]*t2*t22;
|
|
ftype t56 = t51+t52+t53+t54+t55-t85-t86;
|
|
ftype t57 = P[6][5]*t2*t10;
|
|
ftype t58 = P[0][5]*t2*t5;
|
|
ftype t59 = P[1][5]*t2*t15;
|
|
ftype t60 = P[2][5]*t2*t19;
|
|
ftype t61 = P[5][5]*t2*t27;
|
|
ftype t88 = P[4][5]*t2*t7;
|
|
ftype t89 = P[3][5]*t2*t22;
|
|
ftype t62 = t57+t58+t59+t60+t61-t88-t89;
|
|
ftype t63 = t2*t27*t62;
|
|
ftype t64 = P[6][4]*t2*t10;
|
|
ftype t65 = P[0][4]*t2*t5;
|
|
ftype t66 = P[1][4]*t2*t15;
|
|
ftype t67 = P[2][4]*t2*t19;
|
|
ftype t68 = P[5][4]*t2*t27;
|
|
ftype t90 = P[4][4]*t2*t7;
|
|
ftype t91 = P[3][4]*t2*t22;
|
|
ftype t69 = t64+t65+t66+t67+t68-t90-t91;
|
|
ftype t70 = P[6][6]*t2*t10;
|
|
ftype t71 = P[0][6]*t2*t5;
|
|
ftype t72 = P[1][6]*t2*t15;
|
|
ftype t73 = P[2][6]*t2*t19;
|
|
ftype t74 = P[5][6]*t2*t27;
|
|
ftype t93 = P[4][6]*t2*t7;
|
|
ftype t94 = P[3][6]*t2*t22;
|
|
ftype t75 = t70+t71+t72+t73+t74-t93-t94;
|
|
ftype t76 = t2*t10*t75;
|
|
ftype t87 = t2*t22*t56;
|
|
ftype t92 = t2*t7*t69;
|
|
ftype t77 = R_LOS+t37+t43+t50+t63+t76-t87-t92;
|
|
ftype t78;
|
|
|
|
// calculate innovation variance for X axis observation and protect against a badly conditioned calculation
|
|
if (t77 > R_LOS) {
|
|
t78 = 1.0f/t77;
|
|
faultStatus.bad_xflow = false;
|
|
} else {
|
|
t77 = R_LOS;
|
|
t78 = 1.0f/R_LOS;
|
|
faultStatus.bad_xflow = true;
|
|
return;
|
|
}
|
|
flowVarInnov[0] = t77;
|
|
|
|
// calculate innovation for X axis observation
|
|
// flowInnovTime_ms will be updated when Y-axis innovations are calculated
|
|
flowInnov[0] = losPred[0] - ofDataDelayed.flowRadXYcomp.x;
|
|
|
|
// calculate Kalman gains for X-axis observation
|
|
Kfusion[0] = t78*(t12-P[0][4]*t2*t7+P[0][1]*t2*t15+P[0][6]*t2*t10+P[0][2]*t2*t19-P[0][3]*t2*t22+P[0][5]*t2*t27);
|
|
Kfusion[1] = t78*(t31+P[1][0]*t2*t5-P[1][4]*t2*t7+P[1][6]*t2*t10+P[1][2]*t2*t19-P[1][3]*t2*t22+P[1][5]*t2*t27);
|
|
Kfusion[2] = t78*(t47+P[2][0]*t2*t5-P[2][4]*t2*t7+P[2][1]*t2*t15+P[2][6]*t2*t10-P[2][3]*t2*t22+P[2][5]*t2*t27);
|
|
Kfusion[3] = t78*(-t86+P[3][0]*t2*t5-P[3][4]*t2*t7+P[3][1]*t2*t15+P[3][6]*t2*t10+P[3][2]*t2*t19+P[3][5]*t2*t27);
|
|
Kfusion[4] = t78*(-t90+P[4][0]*t2*t5+P[4][1]*t2*t15+P[4][6]*t2*t10+P[4][2]*t2*t19-P[4][3]*t2*t22+P[4][5]*t2*t27);
|
|
Kfusion[5] = t78*(t61+P[5][0]*t2*t5-P[5][4]*t2*t7+P[5][1]*t2*t15+P[5][6]*t2*t10+P[5][2]*t2*t19-P[5][3]*t2*t22);
|
|
Kfusion[6] = t78*(t70+P[6][0]*t2*t5-P[6][4]*t2*t7+P[6][1]*t2*t15+P[6][2]*t2*t19-P[6][3]*t2*t22+P[6][5]*t2*t27);
|
|
Kfusion[7] = t78*(P[7][0]*t2*t5-P[7][4]*t2*t7+P[7][1]*t2*t15+P[7][6]*t2*t10+P[7][2]*t2*t19-P[7][3]*t2*t22+P[7][5]*t2*t27);
|
|
Kfusion[8] = t78*(P[8][0]*t2*t5-P[8][4]*t2*t7+P[8][1]*t2*t15+P[8][6]*t2*t10+P[8][2]*t2*t19-P[8][3]*t2*t22+P[8][5]*t2*t27);
|
|
Kfusion[9] = t78*(P[9][0]*t2*t5-P[9][4]*t2*t7+P[9][1]*t2*t15+P[9][6]*t2*t10+P[9][2]*t2*t19-P[9][3]*t2*t22+P[9][5]*t2*t27);
|
|
|
|
if (!inhibitDelAngBiasStates) {
|
|
Kfusion[10] = t78*(P[10][0]*t2*t5-P[10][4]*t2*t7+P[10][1]*t2*t15+P[10][6]*t2*t10+P[10][2]*t2*t19-P[10][3]*t2*t22+P[10][5]*t2*t27);
|
|
Kfusion[11] = t78*(P[11][0]*t2*t5-P[11][4]*t2*t7+P[11][1]*t2*t15+P[11][6]*t2*t10+P[11][2]*t2*t19-P[11][3]*t2*t22+P[11][5]*t2*t27);
|
|
Kfusion[12] = t78*(P[12][0]*t2*t5-P[12][4]*t2*t7+P[12][1]*t2*t15+P[12][6]*t2*t10+P[12][2]*t2*t19-P[12][3]*t2*t22+P[12][5]*t2*t27);
|
|
} else {
|
|
// zero indexes 10 to 12
|
|
zero_range(&Kfusion[0], 10, 12);
|
|
}
|
|
|
|
if (!inhibitDelVelBiasStates && !badIMUdata) {
|
|
for (uint8_t index = 0; index < 3; index++) {
|
|
const uint8_t stateIndex = index + 13;
|
|
if (!dvelBiasAxisInhibit[index]) {
|
|
Kfusion[stateIndex] = t78*(P[stateIndex][0]*t2*t5-P[stateIndex][4]*t2*t7+P[stateIndex][1]*t2*t15+P[stateIndex][6]*t2*t10+P[stateIndex][2]*t2*t19-P[stateIndex][3]*t2*t22+P[stateIndex][5]*t2*t27);
|
|
} else {
|
|
Kfusion[stateIndex] = 0.0f;
|
|
}
|
|
}
|
|
} else {
|
|
// zero indexes 13 to 15
|
|
zero_range(&Kfusion[0], 13, 15);
|
|
}
|
|
|
|
if (!inhibitMagStates) {
|
|
Kfusion[16] = t78*(P[16][0]*t2*t5-P[16][4]*t2*t7+P[16][1]*t2*t15+P[16][6]*t2*t10+P[16][2]*t2*t19-P[16][3]*t2*t22+P[16][5]*t2*t27);
|
|
Kfusion[17] = t78*(P[17][0]*t2*t5-P[17][4]*t2*t7+P[17][1]*t2*t15+P[17][6]*t2*t10+P[17][2]*t2*t19-P[17][3]*t2*t22+P[17][5]*t2*t27);
|
|
Kfusion[18] = t78*(P[18][0]*t2*t5-P[18][4]*t2*t7+P[18][1]*t2*t15+P[18][6]*t2*t10+P[18][2]*t2*t19-P[18][3]*t2*t22+P[18][5]*t2*t27);
|
|
Kfusion[19] = t78*(P[19][0]*t2*t5-P[19][4]*t2*t7+P[19][1]*t2*t15+P[19][6]*t2*t10+P[19][2]*t2*t19-P[19][3]*t2*t22+P[19][5]*t2*t27);
|
|
Kfusion[20] = t78*(P[20][0]*t2*t5-P[20][4]*t2*t7+P[20][1]*t2*t15+P[20][6]*t2*t10+P[20][2]*t2*t19-P[20][3]*t2*t22+P[20][5]*t2*t27);
|
|
Kfusion[21] = t78*(P[21][0]*t2*t5-P[21][4]*t2*t7+P[21][1]*t2*t15+P[21][6]*t2*t10+P[21][2]*t2*t19-P[21][3]*t2*t22+P[21][5]*t2*t27);
|
|
} else {
|
|
// zero indexes 16 to 21
|
|
zero_range(&Kfusion[0], 16, 21);
|
|
}
|
|
|
|
if (!inhibitWindStates && !treatWindStatesAsTruth) {
|
|
Kfusion[22] = t78*(P[22][0]*t2*t5-P[22][4]*t2*t7+P[22][1]*t2*t15+P[22][6]*t2*t10+P[22][2]*t2*t19-P[22][3]*t2*t22+P[22][5]*t2*t27);
|
|
Kfusion[23] = t78*(P[23][0]*t2*t5-P[23][4]*t2*t7+P[23][1]*t2*t15+P[23][6]*t2*t10+P[23][2]*t2*t19-P[23][3]*t2*t22+P[23][5]*t2*t27);
|
|
} else {
|
|
// zero indexes 22 to 23
|
|
zero_range(&Kfusion[0], 22, 23);
|
|
}
|
|
|
|
} else {
|
|
|
|
// calculate Y axis observation Jacobian
|
|
ftype t2 = 1.0f / range;
|
|
H_LOS[0] = -t2*(q2*vd*-2.0f+q3*ve*2.0f+q0*vn*2.0f);
|
|
H_LOS[1] = -t2*(q3*vd*2.0f+q2*ve*2.0f+q1*vn*2.0f);
|
|
H_LOS[2] = t2*(q0*vd*2.0f-q1*ve*2.0f+q2*vn*2.0f);
|
|
H_LOS[3] = -t2*(q1*vd*2.0f+q0*ve*2.0f-q3*vn*2.0f);
|
|
H_LOS[4] = -t2*(q0*q0+q1*q1-q2*q2-q3*q3);
|
|
H_LOS[5] = -t2*(q0*q3*2.0f+q1*q2*2.0f);
|
|
H_LOS[6] = t2*(q0*q2*2.0f-q1*q3*2.0f);
|
|
|
|
// calculate intermediate variables for the Y observation innovation variance and Kalman gains
|
|
ftype t3 = q3*ve*2.0f;
|
|
ftype t4 = q0*vn*2.0f;
|
|
ftype t11 = q2*vd*2.0f;
|
|
ftype t5 = t3+t4-t11;
|
|
ftype t6 = q0*q3*2.0f;
|
|
ftype t7 = q1*q2*2.0f;
|
|
ftype t8 = t6+t7;
|
|
ftype t9 = q0*q2*2.0f;
|
|
ftype t28 = q1*q3*2.0f;
|
|
ftype t10 = t9-t28;
|
|
ftype t12 = P[0][0]*t2*t5;
|
|
ftype t13 = q3*vd*2.0f;
|
|
ftype t14 = q2*ve*2.0f;
|
|
ftype t15 = q1*vn*2.0f;
|
|
ftype t16 = t13+t14+t15;
|
|
ftype t17 = q0*vd*2.0f;
|
|
ftype t18 = q2*vn*2.0f;
|
|
ftype t29 = q1*ve*2.0f;
|
|
ftype t19 = t17+t18-t29;
|
|
ftype t20 = q1*vd*2.0f;
|
|
ftype t21 = q0*ve*2.0f;
|
|
ftype t30 = q3*vn*2.0f;
|
|
ftype t22 = t20+t21-t30;
|
|
ftype t23 = q0*q0;
|
|
ftype t24 = q1*q1;
|
|
ftype t25 = q2*q2;
|
|
ftype t26 = q3*q3;
|
|
ftype t27 = t23+t24-t25-t26;
|
|
ftype t31 = P[1][1]*t2*t16;
|
|
ftype t32 = P[5][0]*t2*t8;
|
|
ftype t33 = P[1][0]*t2*t16;
|
|
ftype t34 = P[3][0]*t2*t22;
|
|
ftype t35 = P[4][0]*t2*t27;
|
|
ftype t80 = P[6][0]*t2*t10;
|
|
ftype t81 = P[2][0]*t2*t19;
|
|
ftype t36 = t12+t32+t33+t34+t35-t80-t81;
|
|
ftype t37 = t2*t5*t36;
|
|
ftype t38 = P[5][1]*t2*t8;
|
|
ftype t39 = P[0][1]*t2*t5;
|
|
ftype t40 = P[3][1]*t2*t22;
|
|
ftype t41 = P[4][1]*t2*t27;
|
|
ftype t82 = P[6][1]*t2*t10;
|
|
ftype t83 = P[2][1]*t2*t19;
|
|
ftype t42 = t31+t38+t39+t40+t41-t82-t83;
|
|
ftype t43 = t2*t16*t42;
|
|
ftype t44 = P[5][2]*t2*t8;
|
|
ftype t45 = P[0][2]*t2*t5;
|
|
ftype t46 = P[1][2]*t2*t16;
|
|
ftype t47 = P[3][2]*t2*t22;
|
|
ftype t48 = P[4][2]*t2*t27;
|
|
ftype t79 = P[2][2]*t2*t19;
|
|
ftype t84 = P[6][2]*t2*t10;
|
|
ftype t49 = t44+t45+t46+t47+t48-t79-t84;
|
|
ftype t50 = P[5][3]*t2*t8;
|
|
ftype t51 = P[0][3]*t2*t5;
|
|
ftype t52 = P[1][3]*t2*t16;
|
|
ftype t53 = P[3][3]*t2*t22;
|
|
ftype t54 = P[4][3]*t2*t27;
|
|
ftype t86 = P[6][3]*t2*t10;
|
|
ftype t87 = P[2][3]*t2*t19;
|
|
ftype t55 = t50+t51+t52+t53+t54-t86-t87;
|
|
ftype t56 = t2*t22*t55;
|
|
ftype t57 = P[5][4]*t2*t8;
|
|
ftype t58 = P[0][4]*t2*t5;
|
|
ftype t59 = P[1][4]*t2*t16;
|
|
ftype t60 = P[3][4]*t2*t22;
|
|
ftype t61 = P[4][4]*t2*t27;
|
|
ftype t88 = P[6][4]*t2*t10;
|
|
ftype t89 = P[2][4]*t2*t19;
|
|
ftype t62 = t57+t58+t59+t60+t61-t88-t89;
|
|
ftype t63 = t2*t27*t62;
|
|
ftype t64 = P[5][5]*t2*t8;
|
|
ftype t65 = P[0][5]*t2*t5;
|
|
ftype t66 = P[1][5]*t2*t16;
|
|
ftype t67 = P[3][5]*t2*t22;
|
|
ftype t68 = P[4][5]*t2*t27;
|
|
ftype t90 = P[6][5]*t2*t10;
|
|
ftype t91 = P[2][5]*t2*t19;
|
|
ftype t69 = t64+t65+t66+t67+t68-t90-t91;
|
|
ftype t70 = t2*t8*t69;
|
|
ftype t71 = P[5][6]*t2*t8;
|
|
ftype t72 = P[0][6]*t2*t5;
|
|
ftype t73 = P[1][6]*t2*t16;
|
|
ftype t74 = P[3][6]*t2*t22;
|
|
ftype t75 = P[4][6]*t2*t27;
|
|
ftype t92 = P[6][6]*t2*t10;
|
|
ftype t93 = P[2][6]*t2*t19;
|
|
ftype t76 = t71+t72+t73+t74+t75-t92-t93;
|
|
ftype t85 = t2*t19*t49;
|
|
ftype t94 = t2*t10*t76;
|
|
ftype t77 = R_LOS+t37+t43+t56+t63+t70-t85-t94;
|
|
ftype t78;
|
|
|
|
// calculate innovation variance for Y axis observation and protect against a badly conditioned calculation
|
|
if (t77 > R_LOS) {
|
|
t78 = 1.0f/t77;
|
|
faultStatus.bad_yflow = false;
|
|
} else {
|
|
t77 = R_LOS;
|
|
t78 = 1.0f/R_LOS;
|
|
faultStatus.bad_yflow = true;
|
|
return;
|
|
}
|
|
flowVarInnov[1] = t77;
|
|
|
|
// calculate innovation for Y observation
|
|
flowInnov[1] = losPred[1] - ofDataDelayed.flowRadXYcomp.y;
|
|
flowInnovTime_ms = dal.millis();
|
|
|
|
// calculate Kalman gains for the Y-axis observation
|
|
Kfusion[0] = -t78*(t12+P[0][5]*t2*t8-P[0][6]*t2*t10+P[0][1]*t2*t16-P[0][2]*t2*t19+P[0][3]*t2*t22+P[0][4]*t2*t27);
|
|
Kfusion[1] = -t78*(t31+P[1][0]*t2*t5+P[1][5]*t2*t8-P[1][6]*t2*t10-P[1][2]*t2*t19+P[1][3]*t2*t22+P[1][4]*t2*t27);
|
|
Kfusion[2] = -t78*(-t79+P[2][0]*t2*t5+P[2][5]*t2*t8-P[2][6]*t2*t10+P[2][1]*t2*t16+P[2][3]*t2*t22+P[2][4]*t2*t27);
|
|
Kfusion[3] = -t78*(t53+P[3][0]*t2*t5+P[3][5]*t2*t8-P[3][6]*t2*t10+P[3][1]*t2*t16-P[3][2]*t2*t19+P[3][4]*t2*t27);
|
|
Kfusion[4] = -t78*(t61+P[4][0]*t2*t5+P[4][5]*t2*t8-P[4][6]*t2*t10+P[4][1]*t2*t16-P[4][2]*t2*t19+P[4][3]*t2*t22);
|
|
Kfusion[5] = -t78*(t64+P[5][0]*t2*t5-P[5][6]*t2*t10+P[5][1]*t2*t16-P[5][2]*t2*t19+P[5][3]*t2*t22+P[5][4]*t2*t27);
|
|
Kfusion[6] = -t78*(-t92+P[6][0]*t2*t5+P[6][5]*t2*t8+P[6][1]*t2*t16-P[6][2]*t2*t19+P[6][3]*t2*t22+P[6][4]*t2*t27);
|
|
Kfusion[7] = -t78*(P[7][0]*t2*t5+P[7][5]*t2*t8-P[7][6]*t2*t10+P[7][1]*t2*t16-P[7][2]*t2*t19+P[7][3]*t2*t22+P[7][4]*t2*t27);
|
|
Kfusion[8] = -t78*(P[8][0]*t2*t5+P[8][5]*t2*t8-P[8][6]*t2*t10+P[8][1]*t2*t16-P[8][2]*t2*t19+P[8][3]*t2*t22+P[8][4]*t2*t27);
|
|
Kfusion[9] = -t78*(P[9][0]*t2*t5+P[9][5]*t2*t8-P[9][6]*t2*t10+P[9][1]*t2*t16-P[9][2]*t2*t19+P[9][3]*t2*t22+P[9][4]*t2*t27);
|
|
|
|
if (!inhibitDelAngBiasStates) {
|
|
Kfusion[10] = -t78*(P[10][0]*t2*t5+P[10][5]*t2*t8-P[10][6]*t2*t10+P[10][1]*t2*t16-P[10][2]*t2*t19+P[10][3]*t2*t22+P[10][4]*t2*t27);
|
|
Kfusion[11] = -t78*(P[11][0]*t2*t5+P[11][5]*t2*t8-P[11][6]*t2*t10+P[11][1]*t2*t16-P[11][2]*t2*t19+P[11][3]*t2*t22+P[11][4]*t2*t27);
|
|
Kfusion[12] = -t78*(P[12][0]*t2*t5+P[12][5]*t2*t8-P[12][6]*t2*t10+P[12][1]*t2*t16-P[12][2]*t2*t19+P[12][3]*t2*t22+P[12][4]*t2*t27);
|
|
} else {
|
|
// zero indexes 10 to 12
|
|
zero_range(&Kfusion[0], 10, 12);
|
|
}
|
|
|
|
if (!inhibitDelVelBiasStates && !badIMUdata) {
|
|
for (uint8_t index = 0; index < 3; index++) {
|
|
const uint8_t stateIndex = index + 13;
|
|
if (!dvelBiasAxisInhibit[index]) {
|
|
Kfusion[stateIndex] = -t78*(P[stateIndex][0]*t2*t5+P[stateIndex][5]*t2*t8-P[stateIndex][6]*t2*t10+P[stateIndex][1]*t2*t16-P[stateIndex][2]*t2*t19+P[stateIndex][3]*t2*t22+P[stateIndex][4]*t2*t27);
|
|
} else {
|
|
Kfusion[stateIndex] = 0.0f;
|
|
}
|
|
}
|
|
} else {
|
|
// zero indexes 13 to 15
|
|
zero_range(&Kfusion[0], 13, 15);
|
|
}
|
|
|
|
if (!inhibitMagStates) {
|
|
Kfusion[16] = -t78*(P[16][0]*t2*t5+P[16][5]*t2*t8-P[16][6]*t2*t10+P[16][1]*t2*t16-P[16][2]*t2*t19+P[16][3]*t2*t22+P[16][4]*t2*t27);
|
|
Kfusion[17] = -t78*(P[17][0]*t2*t5+P[17][5]*t2*t8-P[17][6]*t2*t10+P[17][1]*t2*t16-P[17][2]*t2*t19+P[17][3]*t2*t22+P[17][4]*t2*t27);
|
|
Kfusion[18] = -t78*(P[18][0]*t2*t5+P[18][5]*t2*t8-P[18][6]*t2*t10+P[18][1]*t2*t16-P[18][2]*t2*t19+P[18][3]*t2*t22+P[18][4]*t2*t27);
|
|
Kfusion[19] = -t78*(P[19][0]*t2*t5+P[19][5]*t2*t8-P[19][6]*t2*t10+P[19][1]*t2*t16-P[19][2]*t2*t19+P[19][3]*t2*t22+P[19][4]*t2*t27);
|
|
Kfusion[20] = -t78*(P[20][0]*t2*t5+P[20][5]*t2*t8-P[20][6]*t2*t10+P[20][1]*t2*t16-P[20][2]*t2*t19+P[20][3]*t2*t22+P[20][4]*t2*t27);
|
|
Kfusion[21] = -t78*(P[21][0]*t2*t5+P[21][5]*t2*t8-P[21][6]*t2*t10+P[21][1]*t2*t16-P[21][2]*t2*t19+P[21][3]*t2*t22+P[21][4]*t2*t27);
|
|
} else {
|
|
// zero indexes 16 to 21
|
|
zero_range(&Kfusion[0], 16, 21);
|
|
}
|
|
|
|
if (!inhibitWindStates && !treatWindStatesAsTruth) {
|
|
Kfusion[22] = -t78*(P[22][0]*t2*t5+P[22][5]*t2*t8-P[22][6]*t2*t10+P[22][1]*t2*t16-P[22][2]*t2*t19+P[22][3]*t2*t22+P[22][4]*t2*t27);
|
|
Kfusion[23] = -t78*(P[23][0]*t2*t5+P[23][5]*t2*t8-P[23][6]*t2*t10+P[23][1]*t2*t16-P[23][2]*t2*t19+P[23][3]*t2*t22+P[23][4]*t2*t27);
|
|
} else {
|
|
// zero indexes 22 to 23
|
|
zero_range(&Kfusion[0], 22, 23);
|
|
}
|
|
}
|
|
|
|
// calculate the innovation consistency test ratio
|
|
flowTestRatio[obsIndex] = sq(flowInnov[obsIndex]) / (sq(MAX(0.01f * (ftype)frontend->_flowInnovGate, 1.0f)) * flowVarInnov[obsIndex]);
|
|
|
|
// Check the innovation for consistency and don't fuse if out of bounds or flow is too fast to be reliable
|
|
if (really_fuse && (flowTestRatio[obsIndex]) < 1.0f && (ofDataDelayed.flowRadXY.x < frontend->_maxFlowRate) && (ofDataDelayed.flowRadXY.y < frontend->_maxFlowRate)) {
|
|
// record the last time observations were accepted for fusion
|
|
prevFlowFuseTime_ms = imuSampleTime_ms;
|
|
// notify first time only
|
|
if (!flowFusionActive) {
|
|
flowFusionActive = true;
|
|
GCS_SEND_TEXT(MAV_SEVERITY_INFO, "EKF3 IMU%u fusing optical flow",(unsigned)imu_index);
|
|
}
|
|
// correct the covariance P = (I - K*H)*P
|
|
// take advantage of the empty columns in KH to reduce the
|
|
// number of operations
|
|
for (uint8_t i = 0; i<=stateIndexLim; i++) {
|
|
for (uint8_t j = 0; j<=6; j++) {
|
|
KH[i][j] = Kfusion[i] * H_LOS[j];
|
|
}
|
|
for (uint8_t j = 7; j<=stateIndexLim; j++) {
|
|
KH[i][j] = 0.0f;
|
|
}
|
|
}
|
|
for (uint8_t j = 0; j<=stateIndexLim; j++) {
|
|
for (uint8_t i = 0; i<=stateIndexLim; i++) {
|
|
ftype res = 0;
|
|
res += KH[i][0] * P[0][j];
|
|
res += KH[i][1] * P[1][j];
|
|
res += KH[i][2] * P[2][j];
|
|
res += KH[i][3] * P[3][j];
|
|
res += KH[i][4] * P[4][j];
|
|
res += KH[i][5] * P[5][j];
|
|
res += KH[i][6] * P[6][j];
|
|
KHP[i][j] = res;
|
|
}
|
|
}
|
|
|
|
// Check that we are not going to drive any variances negative and skip the update if so
|
|
bool healthyFusion = true;
|
|
for (uint8_t i= 0; i<=stateIndexLim; i++) {
|
|
if (KHP[i][i] > P[i][i]) {
|
|
healthyFusion = false;
|
|
}
|
|
}
|
|
|
|
if (healthyFusion) {
|
|
// update the covariance matrix
|
|
for (uint8_t i= 0; i<=stateIndexLim; i++) {
|
|
for (uint8_t j= 0; j<=stateIndexLim; j++) {
|
|
P[i][j] = P[i][j] - KHP[i][j];
|
|
}
|
|
}
|
|
|
|
// force the covariance matrix to be symmetrical and limit the variances to prevent ill-conditioning.
|
|
ForceSymmetry();
|
|
ConstrainVariances();
|
|
|
|
// correct the state vector
|
|
for (uint8_t j= 0; j<=stateIndexLim; j++) {
|
|
statesArray[j] = statesArray[j] - Kfusion[j] * flowInnov[obsIndex];
|
|
}
|
|
stateStruct.quat.normalize();
|
|
|
|
} else {
|
|
// record bad axis
|
|
if (obsIndex == 0) {
|
|
faultStatus.bad_xflow = true;
|
|
} else if (obsIndex == 1) {
|
|
faultStatus.bad_yflow = true;
|
|
}
|
|
|
|
}
|
|
}
|
|
}
|
|
|
|
// store optical flow rates for use in external calibration
|
|
flowCalSample.timestamp_ms = imuSampleTime_ms;
|
|
flowCalSample.flowRate.x = ofDataDelayed.flowRadXY.x;
|
|
flowCalSample.flowRate.y = ofDataDelayed.flowRadXY.y;
|
|
flowCalSample.bodyRate.x = ofDataDelayed.bodyRadXYZ.x;
|
|
flowCalSample.bodyRate.y = ofDataDelayed.bodyRadXYZ.y;
|
|
flowCalSample.losPred.x = losPred[0];
|
|
flowCalSample.losPred.y = losPred[1];
|
|
}
|
|
|
|
// retrieve latest corrected optical flow samples (used for calibration)
|
|
bool NavEKF3_core::getOptFlowSample(uint32_t& timestamp_ms, Vector2f& flowRate, Vector2f& bodyRate, Vector2f& losPred) const
|
|
{
|
|
if (flowCalSample.timestamp_ms != 0) {
|
|
timestamp_ms = flowCalSample.timestamp_ms;
|
|
flowRate = flowCalSample.flowRate;
|
|
bodyRate = flowCalSample.bodyRate;
|
|
losPred = flowCalSample.losPred;
|
|
return true;
|
|
}
|
|
return false;
|
|
}
|
|
|
|
/********************************************************
|
|
* MISC FUNCTIONS *
|
|
********************************************************/
|
|
|
|
#endif // EK3_FEATURE_OPTFLOW_FUSION
|