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- #include <AP_HAL/AP_HAL.h>
- #include "AP_NavEKF3.h"
- #include "AP_NavEKF3_core.h"
- #include <AP_AHRS/AP_AHRS.h>
- #include <AP_Vehicle/AP_Vehicle.h>
- #include <GCS_MAVLink/GCS.h>
- #include <AP_GPS/AP_GPS.h>
- extern const AP_HAL::HAL& hal;
- /* Monitor GPS data to see if quality is good enough to initialise the EKF
- Monitor magnetometer innovations to see if the heading is good enough to use GPS
- Return true if all criteria pass for 10 seconds
- We also record the failure reason so that prearm_failure_reason()
- can give a good report to the user on why arming is failing
- */
- void NavEKF3_core::calcGpsGoodToAlign(void)
- {
- if (inFlight && assume_zero_sideslip() && !use_compass()) {
- // this is a special case where a plane has launched without magnetometer
- // is now in the air and needs to align yaw to the GPS and start navigating as soon as possible
- gpsGoodToAlign = true;
- return;
- }
- // User defined multiplier to be applied to check thresholds
- float checkScaler = 0.01f*(float)frontend->_gpsCheckScaler;
- if (gpsGoodToAlign) {
- /*
- if we have already passed GPS alignment checks then raise
- the check threshold so that we have some hysterisis and
- don't continuously change from able to arm to not able to
- arm
- */
- checkScaler *= 1.3f;
- }
-
- // If we have good magnetometer consistency and bad innovations for longer than 5 seconds then we reset heading and field states
- // This enables us to handle large changes to the external magnetic field environment that occur before arming
- if ((magTestRatio.x <= 1.0f && magTestRatio.y <= 1.0f && yawTestRatio <= 1.0f) || !consistentMagData) {
- magYawResetTimer_ms = imuSampleTime_ms;
- }
- if ((imuSampleTime_ms - magYawResetTimer_ms > 5000) && !motorsArmed) {
- // request reset of heading and magnetic field states
- magYawResetRequest = true;
- // reset timer to ensure that bad magnetometer data cannot cause a heading reset more often than every 5 seconds
- magYawResetTimer_ms = imuSampleTime_ms;
- }
- // Check for significant change in GPS position if disarmed which indicates bad GPS
- // This check can only be used when the vehicle is stationary
- const AP_GPS &gps = AP::gps();
- const struct Location &gpsloc = gps.location(); // Current location
- const float posFiltTimeConst = 10.0f; // time constant used to decay position drift
- // calculate time lapsed since last update and limit to prevent numerical errors
- float deltaTime = constrain_float(float(imuDataDelayed.time_ms - lastPreAlignGpsCheckTime_ms)*0.001f,0.01f,posFiltTimeConst);
- lastPreAlignGpsCheckTime_ms = imuDataDelayed.time_ms;
- // Sum distance moved
- gpsDriftNE += gpsloc_prev.get_distance(gpsloc);
- gpsloc_prev = gpsloc;
- // Decay distance moved exponentially to zero
- gpsDriftNE *= (1.0f - deltaTime/posFiltTimeConst);
- // Clamp the filter state to prevent excessive persistence of large transients
- gpsDriftNE = MIN(gpsDriftNE,10.0f);
- // Fail if more than 3 metres drift after filtering whilst on-ground
- // This corresponds to a maximum acceptable average drift rate of 0.3 m/s or single glitch event of 3m
- bool gpsDriftFail = (gpsDriftNE > 3.0f*checkScaler) && onGround && (frontend->_gpsCheck & MASK_GPS_POS_DRIFT);
- // Report check result as a text string and bitmask
- if (gpsDriftFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "GPS drift %.1fm (needs %.1f)", (double)gpsDriftNE, (double)(3.0f*checkScaler));
- gpsCheckStatus.bad_horiz_drift = true;
- } else {
- gpsCheckStatus.bad_horiz_drift = false;
- }
- // Check that the vertical GPS vertical velocity is reasonable after noise filtering
- bool gpsVertVelFail;
- if (gps.have_vertical_velocity() && onGround) {
- // check that the average vertical GPS velocity is close to zero
- gpsVertVelFilt = 0.1f * gpsDataNew.vel.z + 0.9f * gpsVertVelFilt;
- gpsVertVelFilt = constrain_float(gpsVertVelFilt,-10.0f,10.0f);
- gpsVertVelFail = (fabsf(gpsVertVelFilt) > 0.3f*checkScaler) && (frontend->_gpsCheck & MASK_GPS_VERT_SPD);
- } else if ((frontend->_fusionModeGPS == 0) && !gps.have_vertical_velocity()) {
- // If the EKF settings require vertical GPS velocity and the receiver is not outputting it, then fail
- gpsVertVelFail = true;
- // if we have a 3D fix with no vertical velocity and
- // EK3_GPS_TYPE=0 then change it to 1. It means the GPS is not
- // capable of giving a vertical velocity
- if (gps.status() >= AP_GPS::GPS_OK_FIX_3D) {
- frontend->_fusionModeGPS.set(1);
- gcs().send_text(MAV_SEVERITY_WARNING, "EK3: Changed EK3_GPS_TYPE to 1");
- }
- } else {
- gpsVertVelFail = false;
- }
- // Report check result as a text string and bitmask
- if (gpsVertVelFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "GPS vertical speed %.2fm/s (needs %.2f)", (double)fabsf(gpsVertVelFilt), (double)(0.3f*checkScaler));
- gpsCheckStatus.bad_vert_vel = true;
- } else {
- gpsCheckStatus.bad_vert_vel = false;
- }
- // Check that the horizontal GPS vertical velocity is reasonable after noise filtering
- // This check can only be used if the vehicle is stationary
- bool gpsHorizVelFail;
- if (onGround) {
- gpsHorizVelFilt = 0.1f * norm(gpsDataDelayed.vel.x,gpsDataDelayed.vel.y) + 0.9f * gpsHorizVelFilt;
- gpsHorizVelFilt = constrain_float(gpsHorizVelFilt,-10.0f,10.0f);
- gpsHorizVelFail = (fabsf(gpsHorizVelFilt) > 0.3f*checkScaler) && (frontend->_gpsCheck & MASK_GPS_HORIZ_SPD);
- } else {
- gpsHorizVelFail = false;
- }
- // Report check result as a text string and bitmask
- if (gpsHorizVelFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "GPS horizontal speed %.2fm/s (needs %.2f)", (double)gpsDriftNE, (double)(0.3f*checkScaler));
- gpsCheckStatus.bad_horiz_vel = true;
- } else {
- gpsCheckStatus.bad_horiz_vel = false;
- }
- // fail if horiziontal position accuracy not sufficient
- float hAcc = 0.0f;
- bool hAccFail;
- if (gps.horizontal_accuracy(hAcc)) {
- hAccFail = (hAcc > 5.0f*checkScaler) && (frontend->_gpsCheck & MASK_GPS_POS_ERR);
- } else {
- hAccFail = false;
- }
- // Report check result as a text string and bitmask
- if (hAccFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "GPS horiz error %.1fm (needs %.1f)", (double)hAcc, (double)(5.0f*checkScaler));
- gpsCheckStatus.bad_hAcc = true;
- } else {
- gpsCheckStatus.bad_hAcc = false;
- }
- // Check for vertical GPS accuracy
- float vAcc = 0.0f;
- bool vAccFail = false;
- if (gps.vertical_accuracy(vAcc)) {
- vAccFail = (vAcc > 7.5f * checkScaler) && (frontend->_gpsCheck & MASK_GPS_POS_ERR);
- }
- // Report check result as a text string and bitmask
- if (vAccFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "GPS vert error %.1fm (needs < %.1f)", (double)vAcc, (double)(7.5f * checkScaler));
- gpsCheckStatus.bad_vAcc = true;
- } else {
- gpsCheckStatus.bad_vAcc = false;
- }
- // fail if reported speed accuracy greater than threshold
- bool gpsSpdAccFail = (gpsSpdAccuracy > 1.0f*checkScaler) && (frontend->_gpsCheck & MASK_GPS_SPD_ERR);
- // Report check result as a text string and bitmask
- if (gpsSpdAccFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "GPS speed error %.1f (needs < %.1f)", (double)gpsSpdAccuracy, (double)(1.0f*checkScaler));
- gpsCheckStatus.bad_sAcc = true;
- } else {
- gpsCheckStatus.bad_sAcc = false;
- }
- // fail if satellite geometry is poor
- bool hdopFail = (gps.get_hdop() > 250) && (frontend->_gpsCheck & MASK_GPS_HDOP);
- // Report check result as a text string and bitmask
- if (hdopFail) {
- hal.util->snprintf(prearm_fail_string, sizeof(prearm_fail_string),
- "GPS HDOP %.1f (needs 2.5)", (double)(0.01f * gps.get_hdop()));
- gpsCheckStatus.bad_hdop = true;
- } else {
- gpsCheckStatus.bad_hdop = false;
- }
- // fail if not enough sats
- bool numSatsFail = (gps.num_sats() < 6) && (frontend->_gpsCheck & MASK_GPS_NSATS);
- // Report check result as a text string and bitmask
- if (numSatsFail) {
- hal.util->snprintf(prearm_fail_string, sizeof(prearm_fail_string),
- "GPS numsats %u (needs 6)", gps.num_sats());
- gpsCheckStatus.bad_sats = true;
- } else {
- gpsCheckStatus.bad_sats = false;
- }
- // fail if magnetometer innovations are outside limits indicating bad yaw
- // with bad yaw we are unable to use GPS
- bool yawFail;
- if ((magTestRatio.x > 1.0f || magTestRatio.y > 1.0f || yawTestRatio > 1.0f) && (frontend->_gpsCheck & MASK_GPS_YAW_ERR)) {
- yawFail = true;
- } else {
- yawFail = false;
- }
- // Report check result as a text string and bitmask
- if (yawFail) {
- hal.util->snprintf(prearm_fail_string,
- sizeof(prearm_fail_string),
- "Mag yaw error x=%.1f y=%.1f",
- (double)magTestRatio.x,
- (double)magTestRatio.y);
- gpsCheckStatus.bad_yaw = true;
- } else {
- gpsCheckStatus.bad_yaw = false;
- }
- // assume failed first time through and notify user checks have started
- if (lastGpsVelFail_ms == 0) {
- hal.util->snprintf(prearm_fail_string, sizeof(prearm_fail_string), "EKF starting GPS checks");
- lastGpsVelFail_ms = imuSampleTime_ms;
- }
- // record time of pass or fail
- if (gpsSpdAccFail || numSatsFail || hdopFail || hAccFail || vAccFail || yawFail || gpsDriftFail || gpsVertVelFail || gpsHorizVelFail) {
- lastGpsVelFail_ms = imuSampleTime_ms;
- } else {
- lastGpsVelPass_ms = imuSampleTime_ms;
- }
- // continuous period of 10s without fail required to set healthy
- // continuous period of 5s without pass required to set unhealthy
- if (!gpsGoodToAlign && imuSampleTime_ms - lastGpsVelFail_ms > 10000) {
- gpsGoodToAlign = true;
- } else if (gpsGoodToAlign && imuSampleTime_ms - lastGpsVelPass_ms > 5000) {
- gpsGoodToAlign = false;
- }
- }
- // update inflight calculaton that determines if GPS data is good enough for reliable navigation
- void NavEKF3_core::calcGpsGoodForFlight(void)
- {
- // use a simple criteria based on the GPS receivers claimed speed accuracy and the EKF innovation consistency checks
- // set up varaibles and constants used by filter that is applied to GPS speed accuracy
- const float alpha1 = 0.2f; // coefficient for first stage LPF applied to raw speed accuracy data
- const float tau = 10.0f; // time constant (sec) of peak hold decay
- if (lastGpsCheckTime_ms == 0) {
- lastGpsCheckTime_ms = imuSampleTime_ms;
- }
- float dtLPF = (imuSampleTime_ms - lastGpsCheckTime_ms) * 1e-3f;
- lastGpsCheckTime_ms = imuSampleTime_ms;
- float alpha2 = constrain_float(dtLPF/tau,0.0f,1.0f);
- // get the receivers reported speed accuracy
- float gpsSpdAccRaw;
- if (!AP::gps().speed_accuracy(gpsSpdAccRaw)) {
- gpsSpdAccRaw = 0.0f;
- }
- // filter the raw speed accuracy using a LPF
- sAccFilterState1 = constrain_float((alpha1 * gpsSpdAccRaw + (1.0f - alpha1) * sAccFilterState1),0.0f,10.0f);
- // apply a peak hold filter to the LPF output
- sAccFilterState2 = MAX(sAccFilterState1,((1.0f - alpha2) * sAccFilterState2));
- // Apply a threshold test with hysteresis to the filtered GPS speed accuracy data
- if (sAccFilterState2 > 1.5f ) {
- gpsSpdAccPass = false;
- } else if(sAccFilterState2 < 1.0f) {
- gpsSpdAccPass = true;
- }
- // Apply a threshold test with hysteresis to the normalised position and velocity innovations
- // Require a fail for one second and a pass for 10 seconds to transition
- if (lastInnovFailTime_ms == 0) {
- lastInnovFailTime_ms = imuSampleTime_ms;
- lastInnovPassTime_ms = imuSampleTime_ms;
- }
- if (velTestRatio < 1.0f && posTestRatio < 1.0f) {
- lastInnovPassTime_ms = imuSampleTime_ms;
- } else if (velTestRatio > 0.7f || posTestRatio > 0.7f) {
- lastInnovFailTime_ms = imuSampleTime_ms;
- }
- if ((imuSampleTime_ms - lastInnovPassTime_ms) > 1000) {
- ekfInnovationsPass = false;
- } else if ((imuSampleTime_ms - lastInnovFailTime_ms) > 10000) {
- ekfInnovationsPass = true;
- }
- // both GPS speed accuracy and EKF innovations must pass
- gpsAccuracyGood = gpsSpdAccPass && ekfInnovationsPass;
- }
- // Detect if we are in flight or on ground
- void NavEKF3_core::detectFlight()
- {
- /*
- If we are a fly forward type vehicle (eg plane), then in-air status can be determined through a combination of speed and height criteria.
- Because of the differing certainty requirements of algorithms that need the in-flight / on-ground status we use two booleans where
- onGround indicates a high certainty we are not flying and inFlight indicates a high certainty we are flying. It is possible for
- both onGround and inFlight to be false if the status is uncertain, but they cannot both be true.
- If we are a plane as indicated by the assume_zero_sideslip() status, then different logic is used
- TODO - this logic should be moved out of the EKF and into the flight vehicle code.
- */
- if (assume_zero_sideslip()) {
- // To be confident we are in the air we use a criteria which combines arm status, ground speed, airspeed and height change
- float gndSpdSq = sq(gpsDataDelayed.vel.x) + sq(gpsDataDelayed.vel.y);
- bool highGndSpd = false;
- bool highAirSpd = false;
- bool largeHgtChange = false;
- // trigger at 8 m/s airspeed
- if (_ahrs->airspeed_sensor_enabled()) {
- const AP_Airspeed *airspeed = _ahrs->get_airspeed();
- if (airspeed->get_airspeed() * AP::ahrs().get_EAS2TAS() > 10.0f) {
- highAirSpd = true;
- }
- }
- // trigger at 10 m/s GPS velocity, but not if GPS is reporting bad velocity errors
- if (gndSpdSq > 100.0f && gpsSpdAccuracy < 1.0f) {
- highGndSpd = true;
- }
- // trigger if more than 10m away from initial height
- if (fabsf(hgtMea) > 10.0f) {
- largeHgtChange = true;
- }
- // Determine to a high certainty we are flying
- if (motorsArmed && highGndSpd && (highAirSpd || largeHgtChange)) {
- onGround = false;
- inFlight = true;
- }
- // if is possible we are in flight, set the time this condition was last detected
- if (motorsArmed && (highGndSpd || highAirSpd || largeHgtChange)) {
- airborneDetectTime_ms = imuSampleTime_ms;
- onGround = false;
- }
- // Determine to a high certainty we are not flying
- // after 5 seconds of not detecting a possible flight condition or we are disarmed, we transition to on-ground mode
- if(!motorsArmed || ((imuSampleTime_ms - airborneDetectTime_ms) > 5000)) {
- onGround = true;
- inFlight = false;
- }
- } else {
- // Non fly forward vehicle, so can only use height and motor arm status
- // If the motors are armed then we could be flying and if they are not armed then we are definitely not flying
- if (motorsArmed) {
- onGround = false;
- } else {
- inFlight = false;
- onGround = true;
- }
- if (!onGround) {
- // If height has increased since exiting on-ground, then we definitely are flying
- if ((stateStruct.position.z - posDownAtTakeoff) < -1.5f) {
- inFlight = true;
- }
- // If rangefinder has increased since exiting on-ground, then we definitely are flying
- if ((rangeDataNew.rng - rngAtStartOfFlight) > 0.5f) {
- inFlight = true;
- }
- // If more than 5 seconds since likely_flying was set
- // true, then set inFlight true
- if (_ahrs->get_time_flying_ms() > 5000) {
- inFlight = true;
- }
- }
- }
- // store current on-ground and in-air status for next time
- prevOnGround = onGround;
- prevInFlight = inFlight;
- // Store vehicle height and range prior to takeoff for use in post takeoff checks
- if (onGround) {
- // store vertical position at start of flight to use as a reference for ground relative checks
- posDownAtTakeoff = stateStruct.position.z;
- // store the range finder measurement which will be used as a reference to detect when we have taken off
- rngAtStartOfFlight = rangeDataNew.rng;
- // if the magnetic field states have been set, then continue to update the vertical position
- // quaternion and yaw innovation snapshots to use as a reference when we start to fly.
- if (magStateInitComplete) {
- posDownAtLastMagReset = stateStruct.position.z;
- quatAtLastMagReset = stateStruct.quat;
- yawInnovAtLastMagReset = innovYaw;
- }
- }
- }
- // determine if a takeoff is expected so that we can compensate for expected barometer errors due to ground effect
- bool NavEKF3_core::getTakeoffExpected()
- {
- if (expectGndEffectTakeoff && imuSampleTime_ms - takeoffExpectedSet_ms > frontend->gndEffectTimeout_ms) {
- expectGndEffectTakeoff = false;
- }
- return expectGndEffectTakeoff;
- }
- // called by vehicle code to specify that a takeoff is happening
- // causes the EKF to compensate for expected barometer errors due to ground effect
- void NavEKF3_core::setTakeoffExpected(bool val)
- {
- takeoffExpectedSet_ms = imuSampleTime_ms;
- expectGndEffectTakeoff = val;
- }
- // determine if a touchdown is expected so that we can compensate for expected barometer errors due to ground effect
- bool NavEKF3_core::getTouchdownExpected()
- {
- if (expectGndEffectTouchdown && imuSampleTime_ms - touchdownExpectedSet_ms > frontend->gndEffectTimeout_ms) {
- expectGndEffectTouchdown = false;
- }
- return expectGndEffectTouchdown;
- }
- // called by vehicle code to specify that a touchdown is expected to happen
- // causes the EKF to compensate for expected barometer errors due to ground effect
- void NavEKF3_core::setTouchdownExpected(bool val)
- {
- touchdownExpectedSet_ms = imuSampleTime_ms;
- expectGndEffectTouchdown = val;
- }
- // Set to true if the terrain underneath is stable enough to be used as a height reference
- // in combination with a range finder. Set to false if the terrain underneath the vehicle
- // cannot be used as a height reference
- void NavEKF3_core::setTerrainHgtStable(bool val)
- {
- terrainHgtStableSet_ms = imuSampleTime_ms;
- terrainHgtStable = val;
- }
- // Detect takeoff for optical flow navigation
- void NavEKF3_core::detectOptFlowTakeoff(void)
- {
- if (!onGround && !takeOffDetected && (imuSampleTime_ms - timeAtArming_ms) > 1000) {
- // we are no longer confidently on the ground so check the range finder and gyro for signs of takeoff
- const AP_InertialSensor &ins = AP::ins();
- Vector3f angRateVec;
- Vector3f gyroBias;
- getGyroBias(gyroBias);
- bool dual_ins = ins.use_gyro(0) && ins.use_gyro(1);
- if (dual_ins) {
- angRateVec = (ins.get_gyro(0) + ins.get_gyro(1)) * 0.5f - gyroBias;
- } else {
- angRateVec = ins.get_gyro() - gyroBias;
- }
- takeOffDetected = (takeOffDetected || (angRateVec.length() > 0.1f) || (rangeDataNew.rng > (rngAtStartOfFlight + 0.1f)));
- } else if (onGround) {
- // we are confidently on the ground so set the takeoff detected status to false
- takeOffDetected = false;
- }
- }
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