vtx: fix VTX_SETTINGS_POWER_COUNT and add dummy entries to saPowerNames
[inav.git] / src / main / navigation / navigation_fixedwing.c
blob71a7f99fc346d20b8724f499a35504c65238351e
1 /*
2 * This file is part of Cleanflight.
4 * Cleanflight is free software: you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation, either version 3 of the License, or
7 * (at your option) any later version.
9 * Cleanflight is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
14 * You should have received a copy of the GNU General Public License
15 * along with Cleanflight. If not, see <http://www.gnu.org/licenses/>.
18 #include <stdbool.h>
19 #include <stdint.h>
20 #include <math.h>
22 #include "platform.h"
24 #include "build/build_config.h"
25 #include "build/debug.h"
27 #include "common/axis.h"
28 #include "common/maths.h"
29 #include "common/filter.h"
31 #include "drivers/time.h"
33 #include "sensors/sensors.h"
34 #include "sensors/acceleration.h"
35 #include "sensors/boardalignment.h"
36 #include "sensors/gyro.h"
37 #include "sensors/pitotmeter.h"
39 #include "flight/pid.h"
40 #include "flight/imu.h"
41 #include "flight/mixer.h"
42 #include "flight/mixer_profile.h"
44 #include "fc/config.h"
45 #include "fc/controlrate_profile.h"
46 #include "fc/rc_controls.h"
47 #include "fc/rc_modes.h"
48 #include "fc/runtime_config.h"
50 #include "navigation/navigation.h"
51 #include "navigation/navigation_private.h"
53 #include "programming/logic_condition.h"
55 #include "rx/rx.h"
57 #include "sensors/battery.h"
59 // Base frequencies for smoothing pitch and roll
60 #define NAV_FW_BASE_PITCH_CUTOFF_FREQUENCY_HZ 2.0f
61 #define NAV_FW_BASE_ROLL_CUTOFF_FREQUENCY_HZ 10.0f
63 // If we are going slower than the minimum ground speed (navConfig()->general.min_ground_speed) - boost throttle to fight against the wind
64 #define NAV_FW_THROTTLE_SPEED_BOOST_GAIN 1.5f
66 // If this is enabled navigation won't be applied if velocity is below 3 m/s
67 //#define NAV_FW_LIMIT_MIN_FLY_VELOCITY
69 static bool isPitchAdjustmentValid = false;
70 static bool isRollAdjustmentValid = false;
71 static bool isYawAdjustmentValid = false;
72 static float throttleSpeedAdjustment = 0;
73 static bool isAutoThrottleManuallyIncreased = false;
74 static float navCrossTrackError;
75 static int8_t loiterDirYaw = 1;
76 bool needToCalculateCircularLoiter;
78 // Calculates the cutoff frequency for smoothing out roll/pitch commands
79 // control_smoothness valid range from 0 to 9
80 // resulting cutoff_freq ranging from baseFreq downwards to ~0.11Hz
81 static float getSmoothnessCutoffFreq(float baseFreq)
83 uint16_t smoothness = 10 - navConfig()->fw.control_smoothness;
84 return 0.001f * baseFreq * (float)(smoothness*smoothness*smoothness) + 0.1f;
87 // Calculates the cutoff frequency for smoothing out pitchToThrottleCorrection
88 // pitch_to_throttle_smooth valid range from 0 to 9
89 // resulting cutoff_freq ranging from baseFreq downwards to ~0.01Hz
90 static float getPitchToThrottleSmoothnessCutoffFreq(float baseFreq)
92 uint16_t smoothness = 10 - navConfig()->fw.pitch_to_throttle_smooth;
93 return 0.001f * baseFreq * (float)(smoothness*smoothness*smoothness) + 0.01f;
96 /*-----------------------------------------------------------
97 * Altitude controller
98 *-----------------------------------------------------------*/
99 void setupFixedWingAltitudeController(void)
101 // TODO
104 void resetFixedWingAltitudeController(void)
106 navPidReset(&posControl.pids.fw_alt);
107 posControl.rcAdjustment[PITCH] = 0;
108 isPitchAdjustmentValid = false;
109 throttleSpeedAdjustment = 0;
112 bool adjustFixedWingAltitudeFromRCInput(void)
114 int16_t rcAdjustment = applyDeadbandRescaled(rcCommand[PITCH], rcControlsConfig()->alt_hold_deadband, -500, 500);
116 if (rcAdjustment) {
117 // set velocity proportional to stick movement
118 float rcClimbRate = -rcAdjustment * navConfig()->fw.max_manual_climb_rate / (500.0f - rcControlsConfig()->alt_hold_deadband);
119 updateClimbRateToAltitudeController(rcClimbRate, 0, ROC_TO_ALT_CONSTANT);
120 return true;
122 else {
123 // Adjusting finished - reset desired position to stay exactly where pilot released the stick
124 if (posControl.flags.isAdjustingAltitude) {
125 updateClimbRateToAltitudeController(0, 0, ROC_TO_ALT_CURRENT);
127 return false;
131 // Position to velocity controller for Z axis
132 static void updateAltitudeVelocityAndPitchController_FW(timeDelta_t deltaMicros)
134 static pt1Filter_t velzFilterState;
136 float desiredClimbRate = getDesiredClimbRate(posControl.desiredState.pos.z, deltaMicros);
138 // Reduce max allowed climb rate by 2/3 if performing loiter (stall prevention)
139 if (needToCalculateCircularLoiter && desiredClimbRate > 0.67f * navConfig()->fw.max_auto_climb_rate) {
140 desiredClimbRate = 0.67f * navConfig()->fw.max_auto_climb_rate;
143 // Here we use negative values for dive for better clarity
144 const float maxClimbDeciDeg = DEGREES_TO_DECIDEGREES(navConfig()->fw.max_climb_angle);
145 const float minDiveDeciDeg = -DEGREES_TO_DECIDEGREES(navConfig()->fw.max_dive_angle);
147 // PID controller to translate desired climb rate error into pitch angle [decideg]
148 float currentClimbRate = navGetCurrentActualPositionAndVelocity()->vel.z;
149 float targetPitchAngle = navPidApply2(&posControl.pids.fw_alt, desiredClimbRate, currentClimbRate, US2S(deltaMicros), minDiveDeciDeg, maxClimbDeciDeg, PID_DTERM_FROM_ERROR);
151 // Apply low-pass filter to prevent rapid correction
152 targetPitchAngle = pt1FilterApply4(&velzFilterState, targetPitchAngle, getSmoothnessCutoffFreq(NAV_FW_BASE_PITCH_CUTOFF_FREQUENCY_HZ), US2S(deltaMicros));
154 // Reconstrain pitch angle (> 0 - climb, < 0 - dive)
155 targetPitchAngle = constrainf(targetPitchAngle, minDiveDeciDeg, maxClimbDeciDeg);
156 posControl.rcAdjustment[PITCH] = targetPitchAngle;
158 posControl.desiredState.vel.z = desiredClimbRate;
159 navDesiredVelocity[Z] = constrain(lrintf(posControl.desiredState.vel.z), -32678, 32767);
162 void applyFixedWingAltitudeAndThrottleController(timeUs_t currentTimeUs)
164 static timeUs_t previousTimePositionUpdate = 0; // Occurs @ altitude sensor update rate (max MAX_ALTITUDE_UPDATE_RATE_HZ)
166 if ((posControl.flags.estAltStatus >= EST_USABLE)) {
167 if (posControl.flags.verticalPositionDataNew) {
168 const timeDeltaLarge_t deltaMicrosPositionUpdate = currentTimeUs - previousTimePositionUpdate;
169 previousTimePositionUpdate = currentTimeUs;
171 // Check if last correction was not too long ago
172 if (deltaMicrosPositionUpdate < MAX_POSITION_UPDATE_INTERVAL_US) {
173 updateAltitudeVelocityAndPitchController_FW(deltaMicrosPositionUpdate);
175 else {
176 // Position update has not occurred in time (first iteration or glitch), reset altitude controller
177 resetFixedWingAltitudeController();
180 // Indicate that information is no longer usable
181 posControl.flags.verticalPositionDataConsumed = true;
184 isPitchAdjustmentValid = true;
186 else {
187 // No valid altitude sensor data, don't adjust pitch automatically, rcCommand[PITCH] is passed through to PID controller
188 isPitchAdjustmentValid = false;
192 /*-----------------------------------------------------------
193 * Adjusts desired heading from pilot's input
194 *-----------------------------------------------------------*/
195 bool adjustFixedWingHeadingFromRCInput(void)
197 if (ABS(rcCommand[YAW]) > rcControlsConfig()->pos_hold_deadband) {
198 return true;
201 return false;
204 /*-----------------------------------------------------------
205 * XY-position controller for multicopter aircraft
206 *-----------------------------------------------------------*/
207 static fpVector3_t virtualDesiredPosition;
208 static pt1Filter_t fwPosControllerCorrectionFilterState;
211 * TODO Currently this function resets both FixedWing and Rover & Boat position controller
213 void resetFixedWingPositionController(void)
215 virtualDesiredPosition.x = 0;
216 virtualDesiredPosition.y = 0;
217 virtualDesiredPosition.z = 0;
219 navPidReset(&posControl.pids.fw_nav);
220 navPidReset(&posControl.pids.fw_heading);
221 posControl.rcAdjustment[ROLL] = 0;
222 posControl.rcAdjustment[YAW] = 0;
223 isRollAdjustmentValid = false;
224 isYawAdjustmentValid = false;
226 pt1FilterReset(&fwPosControllerCorrectionFilterState, 0.0f);
229 static int8_t loiterDirection(void) {
230 int8_t dir = 1; //NAV_LOITER_RIGHT
232 if (navConfig()->fw.loiter_direction == NAV_LOITER_LEFT) {
233 dir = -1;
236 if (navConfig()->fw.loiter_direction == NAV_LOITER_YAW) {
238 if (rcCommand[YAW] < -250) {
239 loiterDirYaw = 1; //RIGHT //yaw is contrariwise
242 if (rcCommand[YAW] > 250) {
243 loiterDirYaw = -1; //LEFT //see annexCode in fc_core.c
246 dir = loiterDirYaw;
249 if (IS_RC_MODE_ACTIVE(BOXLOITERDIRCHN)) {
250 dir *= -1;
253 return dir;
256 static void calculateVirtualPositionTarget_FW(float trackingPeriod)
258 if (FLIGHT_MODE(NAV_COURSE_HOLD_MODE) || posControl.navState == NAV_STATE_FW_LANDING_GLIDE || posControl.navState == NAV_STATE_FW_LANDING_FLARE) {
259 return;
262 float posErrorX = posControl.desiredState.pos.x - navGetCurrentActualPositionAndVelocity()->pos.x;
263 float posErrorY = posControl.desiredState.pos.y - navGetCurrentActualPositionAndVelocity()->pos.y;
265 float distanceToActualTarget = calc_length_pythagorean_2D(posErrorX, posErrorY);
267 // Limit minimum forward velocity to 1 m/s
268 float trackingDistance = trackingPeriod * MAX(posControl.actualState.velXY, 100.0f);
270 uint32_t navLoiterRadius = getLoiterRadius(navConfig()->fw.loiter_radius);
271 fpVector3_t loiterCenterPos = posControl.desiredState.pos;
272 int8_t loiterTurnDirection = loiterDirection();
274 // Detemine if a circular loiter is required.
275 // For waypoints only use circular loiter when angular visibility is > 30 degs, otherwise head straight toward target
276 #define TAN_15DEG 0.26795f
278 bool loiterApproachActive = isNavHoldPositionActive() &&
279 distanceToActualTarget <= (navLoiterRadius / TAN_15DEG) &&
280 distanceToActualTarget > 50.0f;
281 needToCalculateCircularLoiter = loiterApproachActive || (navGetCurrentStateFlags() & NAV_CTL_HOLD);
283 //if vtol landing is required, fly straight to homepoint
284 if ((posControl.navState == NAV_STATE_RTH_HEAD_HOME) && navigationRTHAllowsLanding() && checkMixerATRequired(MIXERAT_REQUEST_LAND)){
285 needToCalculateCircularLoiter = false;
288 /* WP turn smoothing with 2 options, 1: pass through WP, 2: cut inside turn missing WP
289 * Works for turns > 30 degs and < 160 degs.
290 * Option 1 switches to loiter path around waypoint using navLoiterRadius.
291 * Loiter centered on point inside turn at required distance from waypoint and
292 * on a bearing midway between current and next waypoint course bearings.
293 * Option 2 simply uses a normal turn once the turn initiation point is reached */
294 int32_t waypointTurnAngle = posControl.activeWaypoint.nextTurnAngle == -1 ? -1 : ABS(posControl.activeWaypoint.nextTurnAngle);
295 posControl.flags.wpTurnSmoothingActive = false;
296 if (waypointTurnAngle > 3000 && waypointTurnAngle < 16000 && isWaypointNavTrackingActive() && !needToCalculateCircularLoiter) {
297 // turnStartFactor adjusts start of loiter based on turn angle
298 float turnStartFactor;
299 if (navConfig()->fw.wp_turn_smoothing == WP_TURN_SMOOTHING_ON) { // passes through WP
300 turnStartFactor = waypointTurnAngle / 6000.0f;
301 } else { // // cut inside turn missing WP
302 turnStartFactor = constrainf(tan_approx(CENTIDEGREES_TO_RADIANS(waypointTurnAngle / 2.0f)), 1.0f, 2.0f);
304 // velXY provides additional turn initiation distance based on an assumed 1 second delayed turn response time
305 if (posControl.wpDistance < (posControl.actualState.velXY + navLoiterRadius * turnStartFactor)) {
306 if (navConfig()->fw.wp_turn_smoothing == WP_TURN_SMOOTHING_ON) {
307 int32_t loiterCenterBearing = wrap_36000(((wrap_18000(posControl.activeWaypoint.nextTurnAngle - 18000)) / 2) + posControl.activeWaypoint.bearing + 18000);
308 loiterCenterPos.x = posControl.activeWaypoint.pos.x + navLoiterRadius * cos_approx(CENTIDEGREES_TO_RADIANS(loiterCenterBearing));
309 loiterCenterPos.y = posControl.activeWaypoint.pos.y + navLoiterRadius * sin_approx(CENTIDEGREES_TO_RADIANS(loiterCenterBearing));
311 posErrorX = loiterCenterPos.x - navGetCurrentActualPositionAndVelocity()->pos.x;
312 posErrorY = loiterCenterPos.y - navGetCurrentActualPositionAndVelocity()->pos.y;
314 // turn direction to next waypoint
315 loiterTurnDirection = posControl.activeWaypoint.nextTurnAngle > 0 ? 1 : -1; // 1 = right
317 needToCalculateCircularLoiter = true;
319 posControl.flags.wpTurnSmoothingActive = true;
323 // We are closing in on a waypoint, calculate circular loiter if required
324 if (needToCalculateCircularLoiter) {
325 float loiterAngle = atan2_approx(-posErrorY, -posErrorX) + DEGREES_TO_RADIANS(loiterTurnDirection * 45.0f);
326 float loiterTargetX = loiterCenterPos.x + navLoiterRadius * cos_approx(loiterAngle);
327 float loiterTargetY = loiterCenterPos.y + navLoiterRadius * sin_approx(loiterAngle);
329 // We have temporary loiter target. Recalculate distance and position error
330 posErrorX = loiterTargetX - navGetCurrentActualPositionAndVelocity()->pos.x;
331 posErrorY = loiterTargetY - navGetCurrentActualPositionAndVelocity()->pos.y;
332 distanceToActualTarget = calc_length_pythagorean_2D(posErrorX, posErrorY);
335 // Calculate virtual waypoint
336 virtualDesiredPosition.x = navGetCurrentActualPositionAndVelocity()->pos.x + posErrorX * (trackingDistance / distanceToActualTarget);
337 virtualDesiredPosition.y = navGetCurrentActualPositionAndVelocity()->pos.y + posErrorY * (trackingDistance / distanceToActualTarget);
339 // Shift position according to pilot's ROLL input (up to max_manual_speed velocity)
340 if (posControl.flags.isAdjustingPosition) {
341 int16_t rcRollAdjustment = applyDeadbandRescaled(rcCommand[ROLL], rcControlsConfig()->pos_hold_deadband, -500, 500);
343 if (rcRollAdjustment) {
344 float rcShiftY = rcRollAdjustment * navConfig()->general.max_manual_speed / 500.0f * trackingPeriod;
346 // Rotate this target shift from body frame to to earth frame and apply to position target
347 virtualDesiredPosition.x += -rcShiftY * posControl.actualState.sinYaw;
348 virtualDesiredPosition.y += rcShiftY * posControl.actualState.cosYaw;
353 bool adjustFixedWingPositionFromRCInput(void)
355 int16_t rcRollAdjustment = applyDeadbandRescaled(rcCommand[ROLL], rcControlsConfig()->pos_hold_deadband, -500, 500);
356 return (rcRollAdjustment);
359 float processHeadingYawController(timeDelta_t deltaMicros, int32_t navHeadingError, bool errorIsDecreasing) {
360 static float limit = 0.0f;
362 if (limit == 0.0f) {
363 limit = pidProfile()->navFwPosHdgPidsumLimit * 100.0f;
366 const pidControllerFlags_e yawPidFlags = errorIsDecreasing ? PID_SHRINK_INTEGRATOR : 0;
368 const float yawAdjustment = navPidApply2(
369 &posControl.pids.fw_heading,
371 applyDeadband(navHeadingError, navConfig()->fw.yawControlDeadband * 100),
372 US2S(deltaMicros),
373 -limit,
374 limit,
375 yawPidFlags
376 ) * 0.01f;
378 DEBUG_SET(DEBUG_NAV_YAW, 0, posControl.pids.fw_heading.proportional);
379 DEBUG_SET(DEBUG_NAV_YAW, 1, posControl.pids.fw_heading.integral);
380 DEBUG_SET(DEBUG_NAV_YAW, 2, posControl.pids.fw_heading.derivative);
381 DEBUG_SET(DEBUG_NAV_YAW, 3, navHeadingError);
382 DEBUG_SET(DEBUG_NAV_YAW, 4, posControl.pids.fw_heading.output_constrained);
384 return yawAdjustment;
387 static void updatePositionHeadingController_FW(timeUs_t currentTimeUs, timeDelta_t deltaMicros)
389 static timeUs_t previousTimeMonitoringUpdate;
390 static int32_t previousHeadingError;
391 static bool errorIsDecreasing;
392 static bool forceTurnDirection = false;
393 int32_t virtualTargetBearing;
395 if (FLIGHT_MODE(NAV_COURSE_HOLD_MODE) || posControl.navState == NAV_STATE_FW_LANDING_GLIDE || posControl.navState == NAV_STATE_FW_LANDING_FLARE) {
396 virtualTargetBearing = posControl.desiredState.yaw;
397 } else {
398 // We have virtual position target, calculate heading error
399 virtualTargetBearing = calculateBearingToDestination(&virtualDesiredPosition);
402 /* If waypoint tracking enabled quickly force craft toward waypoint course line and closely track along it */
403 if (navConfig()->fw.wp_tracking_accuracy && isWaypointNavTrackingActive() && !needToCalculateCircularLoiter) {
404 // courseVirtualCorrection initially used to determine current position relative to course line for later use
405 int32_t courseVirtualCorrection = wrap_18000(posControl.activeWaypoint.bearing - virtualTargetBearing);
406 navCrossTrackError = ABS(posControl.wpDistance * sin_approx(CENTIDEGREES_TO_RADIANS(courseVirtualCorrection)));
408 // tracking only active when certain distance and heading conditions are met
409 if ((ABS(wrap_18000(virtualTargetBearing - posControl.actualState.cog)) < 9000 || posControl.wpDistance < 1000.0f) && navCrossTrackError > 200) {
410 int32_t courseHeadingError = wrap_18000(posControl.activeWaypoint.bearing - posControl.actualState.cog);
412 // captureFactor adjusts distance/heading sensitivity balance when closing in on course line.
413 // Closing distance threashold based on speed and an assumed 1 second response time.
414 float captureFactor = navCrossTrackError < posControl.actualState.velXY ? constrainf(2.0f - ABS(courseHeadingError) / 500.0f, 0.0f, 2.0f) : 1.0f;
416 // bias between reducing distance to course line and aligning with course heading adjusted by waypoint_tracking_accuracy
417 // initial courseCorrectionFactor based on distance to course line
418 float courseCorrectionFactor = constrainf(captureFactor * navCrossTrackError / (1000.0f * navConfig()->fw.wp_tracking_accuracy), 0.0f, 1.0f);
419 courseCorrectionFactor = courseVirtualCorrection < 0 ? -courseCorrectionFactor : courseCorrectionFactor;
421 // course heading alignment factor
422 float courseHeadingFactor = constrainf(courseHeadingError / 18000.0f, 0.0f, 1.0f);
423 courseHeadingFactor = courseHeadingError < 0 ? -courseHeadingFactor : courseHeadingFactor;
425 // final courseCorrectionFactor combining distance and heading factors
426 courseCorrectionFactor = constrainf(courseCorrectionFactor - courseHeadingFactor, -1.0f, 1.0f);
428 // final courseVirtualCorrection value
429 courseVirtualCorrection = DEGREES_TO_CENTIDEGREES(navConfig()->fw.wp_tracking_max_angle) * courseCorrectionFactor;
430 virtualTargetBearing = wrap_36000(posControl.activeWaypoint.bearing - courseVirtualCorrection);
435 * Calculate NAV heading error
436 * Units are centidegrees
438 int32_t navHeadingError = wrap_18000(virtualTargetBearing - posControl.actualState.cog);
440 // Forced turn direction
441 // If heading error is close to 180 deg we initiate forced turn and only disable it when heading error goes below 90 deg
442 if (ABS(navHeadingError) > 17000) {
443 forceTurnDirection = true;
445 else if (ABS(navHeadingError) < 9000 && forceTurnDirection) {
446 forceTurnDirection = false;
449 // If forced turn direction flag is enabled we fix the sign of the direction
450 if (forceTurnDirection) {
451 navHeadingError = loiterDirection() * ABS(navHeadingError);
454 // Slow error monitoring (2Hz rate)
455 if ((currentTimeUs - previousTimeMonitoringUpdate) >= HZ2US(NAV_FW_CONTROL_MONITORING_RATE)) {
456 // Check if error is decreasing over time
457 errorIsDecreasing = (ABS(previousHeadingError) > ABS(navHeadingError));
459 // Save values for next iteration
460 previousHeadingError = navHeadingError;
461 previousTimeMonitoringUpdate = currentTimeUs;
464 // Only allow PID integrator to shrink if error is decreasing over time
465 const pidControllerFlags_e pidFlags = PID_DTERM_FROM_ERROR | (errorIsDecreasing ? PID_SHRINK_INTEGRATOR : 0);
467 // Input error in (deg*100), output roll angle (deg*100)
468 float rollAdjustment = navPidApply2(&posControl.pids.fw_nav, posControl.actualState.cog + navHeadingError, posControl.actualState.cog, US2S(deltaMicros),
469 -DEGREES_TO_CENTIDEGREES(navConfig()->fw.max_bank_angle),
470 DEGREES_TO_CENTIDEGREES(navConfig()->fw.max_bank_angle),
471 pidFlags);
473 // Apply low-pass filter to prevent rapid correction
474 rollAdjustment = pt1FilterApply4(&fwPosControllerCorrectionFilterState, rollAdjustment, getSmoothnessCutoffFreq(NAV_FW_BASE_ROLL_CUTOFF_FREQUENCY_HZ), US2S(deltaMicros));
476 // Convert rollAdjustment to decidegrees (rcAdjustment holds decidegrees)
477 posControl.rcAdjustment[ROLL] = CENTIDEGREES_TO_DECIDEGREES(rollAdjustment);
480 * Yaw adjustment
481 * It is working in relative mode and we aim to keep error at zero
483 if (STATE(FW_HEADING_USE_YAW)) {
484 posControl.rcAdjustment[YAW] = processHeadingYawController(deltaMicros, navHeadingError, errorIsDecreasing);
485 } else {
486 posControl.rcAdjustment[YAW] = 0;
490 void applyFixedWingPositionController(timeUs_t currentTimeUs)
492 static timeUs_t previousTimePositionUpdate = 0; // Occurs @ GPS update rate
494 // Apply controller only if position source is valid. In absence of valid pos sensor (GPS loss), we'd stick in forced ANGLE mode
495 if ((posControl.flags.estPosStatus >= EST_USABLE)) {
496 // If we have new position - update velocity and acceleration controllers
497 if (posControl.flags.horizontalPositionDataNew) {
498 const timeDeltaLarge_t deltaMicrosPositionUpdate = currentTimeUs - previousTimePositionUpdate;
499 previousTimePositionUpdate = currentTimeUs;
501 if (deltaMicrosPositionUpdate < MAX_POSITION_UPDATE_INTERVAL_US) {
502 // Calculate virtual position target at a distance of forwardVelocity * HZ2S(POSITION_TARGET_UPDATE_RATE_HZ)
503 // Account for pilot's roll input (move position target left/right at max of max_manual_speed)
504 // POSITION_TARGET_UPDATE_RATE_HZ should be chosen keeping in mind that position target shouldn't be reached until next pos update occurs
505 // FIXME: verify the above
506 calculateVirtualPositionTarget_FW(HZ2S(MIN_POSITION_UPDATE_RATE_HZ) * 2);
507 updatePositionHeadingController_FW(currentTimeUs, deltaMicrosPositionUpdate);
508 needToCalculateCircularLoiter = false;
510 else {
511 // Position update has not occurred in time (first iteration or glitch), reset altitude controller
512 resetFixedWingPositionController();
515 // Indicate that information is no longer usable
516 posControl.flags.horizontalPositionDataConsumed = true;
519 isRollAdjustmentValid = true;
520 isYawAdjustmentValid = true;
522 else {
523 // No valid pos sensor data, don't adjust pitch automatically, rcCommand[ROLL] is passed through to PID controller
524 isRollAdjustmentValid = false;
525 isYawAdjustmentValid = false;
529 int16_t applyFixedWingMinSpeedController(timeUs_t currentTimeUs)
531 static timeUs_t previousTimePositionUpdate = 0; // Occurs @ GPS update rate
533 // Apply controller only if position source is valid
534 if ((posControl.flags.estPosStatus >= EST_USABLE)) {
535 // If we have new position - update velocity and acceleration controllers
536 if (posControl.flags.horizontalPositionDataNew) {
537 const timeDeltaLarge_t deltaMicrosPositionUpdate = currentTimeUs - previousTimePositionUpdate;
538 previousTimePositionUpdate = currentTimeUs;
540 if (deltaMicrosPositionUpdate < MAX_POSITION_UPDATE_INTERVAL_US) {
541 float velThrottleBoost = ((navConfig()->general.min_ground_speed * 100.0f) - posControl.actualState.velXY) * NAV_FW_THROTTLE_SPEED_BOOST_GAIN * US2S(deltaMicrosPositionUpdate);
543 // If we are in the deadband of 50cm/s - don't update speed boost
544 if (fabsf(posControl.actualState.velXY - (navConfig()->general.min_ground_speed * 100.0f)) > 50) {
545 throttleSpeedAdjustment += velThrottleBoost;
548 throttleSpeedAdjustment = constrainf(throttleSpeedAdjustment, 0.0f, 500.0f);
550 else {
551 // Position update has not occurred in time (first iteration or glitch), reset altitude controller
552 throttleSpeedAdjustment = 0;
555 // Indicate that information is no longer usable
556 posControl.flags.horizontalPositionDataConsumed = true;
559 else {
560 // No valid pos sensor data, we can't calculate speed
561 throttleSpeedAdjustment = 0;
564 return throttleSpeedAdjustment;
567 int16_t fixedWingPitchToThrottleCorrection(int16_t pitch, timeUs_t currentTimeUs)
569 static timeUs_t previousTimePitchToThrCorr = 0;
570 const timeDeltaLarge_t deltaMicrosPitchToThrCorr = currentTimeUs - previousTimePitchToThrCorr;
571 previousTimePitchToThrCorr = currentTimeUs;
573 static pt1Filter_t pitchToThrFilterState;
575 // Apply low-pass filter to pitch angle to smooth throttle correction
576 int16_t filteredPitch = (int16_t)pt1FilterApply4(&pitchToThrFilterState, pitch, getPitchToThrottleSmoothnessCutoffFreq(NAV_FW_BASE_PITCH_CUTOFF_FREQUENCY_HZ), US2S(deltaMicrosPitchToThrCorr));
578 int16_t pitchToThrottle = currentBatteryProfile->nav.fw.pitch_to_throttle;
580 #ifdef USE_FW_AUTOLAND
581 if (pitch < 0 && posControl.fwLandState.landState == FW_AUTOLAND_STATE_FINAL_APPROACH) {
582 pitchToThrottle *= navFwAutolandConfig()->finalApproachPitchToThrottleMod / 100.0f;
584 #endif
586 if (ABS(pitch - filteredPitch) > navConfig()->fw.pitch_to_throttle_thresh) {
587 // Unfiltered throttle correction outside of pitch deadband
588 return DECIDEGREES_TO_DEGREES(pitch) * pitchToThrottle;
590 else {
591 // Filtered throttle correction inside of pitch deadband
592 return DECIDEGREES_TO_DEGREES(filteredPitch) * pitchToThrottle;
596 void applyFixedWingPitchRollThrottleController(navigationFSMStateFlags_t navStateFlags, timeUs_t currentTimeUs)
598 int16_t minThrottleCorrection = currentBatteryProfile->nav.fw.min_throttle - currentBatteryProfile->nav.fw.cruise_throttle;
599 int16_t maxThrottleCorrection = currentBatteryProfile->nav.fw.max_throttle - currentBatteryProfile->nav.fw.cruise_throttle;
601 if (isRollAdjustmentValid && (navStateFlags & NAV_CTL_POS)) {
602 // ROLL >0 right, <0 left
603 int16_t rollCorrection = constrain(posControl.rcAdjustment[ROLL], -DEGREES_TO_DECIDEGREES(navConfig()->fw.max_bank_angle), DEGREES_TO_DECIDEGREES(navConfig()->fw.max_bank_angle));
604 rcCommand[ROLL] = pidAngleToRcCommand(rollCorrection, pidProfile()->max_angle_inclination[FD_ROLL]);
607 if (isYawAdjustmentValid && (navStateFlags & NAV_CTL_POS)) {
608 rcCommand[YAW] = posControl.rcAdjustment[YAW];
611 if (isPitchAdjustmentValid && (navStateFlags & NAV_CTL_ALT)) {
612 // PITCH >0 dive, <0 climb
613 int16_t pitchCorrection = constrain(posControl.rcAdjustment[PITCH], -DEGREES_TO_DECIDEGREES(navConfig()->fw.max_dive_angle), DEGREES_TO_DECIDEGREES(navConfig()->fw.max_climb_angle));
614 rcCommand[PITCH] = -pidAngleToRcCommand(pitchCorrection, pidProfile()->max_angle_inclination[FD_PITCH]);
615 int16_t throttleCorrection = fixedWingPitchToThrottleCorrection(pitchCorrection, currentTimeUs);
617 if (navStateFlags & NAV_CTL_LAND) {
618 // During LAND we do not allow to raise THROTTLE when nose is up to reduce speed
619 throttleCorrection = constrain(throttleCorrection, minThrottleCorrection, 0);
620 } else {
621 throttleCorrection = constrain(throttleCorrection, minThrottleCorrection, maxThrottleCorrection);
624 // Speed controller - only apply in POS mode when NOT NAV_CTL_LAND
625 if ((navStateFlags & NAV_CTL_POS) && !(navStateFlags & NAV_CTL_LAND)) {
626 throttleCorrection += applyFixedWingMinSpeedController(currentTimeUs);
627 throttleCorrection = constrain(throttleCorrection, minThrottleCorrection, maxThrottleCorrection);
630 uint16_t correctedThrottleValue = constrain(currentBatteryProfile->nav.fw.cruise_throttle + throttleCorrection, currentBatteryProfile->nav.fw.min_throttle, currentBatteryProfile->nav.fw.max_throttle);
632 // Manual throttle increase
633 if (navConfig()->fw.allow_manual_thr_increase && !FLIGHT_MODE(FAILSAFE_MODE) && !FLIGHT_MODE(NAV_FW_AUTOLAND)) {
634 if (rcCommand[THROTTLE] < PWM_RANGE_MIN + (PWM_RANGE_MAX - PWM_RANGE_MIN) * 0.95){
635 correctedThrottleValue += MAX(0, rcCommand[THROTTLE] - currentBatteryProfile->nav.fw.cruise_throttle);
636 } else {
637 correctedThrottleValue = getMaxThrottle();
639 isAutoThrottleManuallyIncreased = (rcCommand[THROTTLE] > currentBatteryProfile->nav.fw.cruise_throttle);
640 } else {
641 isAutoThrottleManuallyIncreased = false;
644 rcCommand[THROTTLE] = setDesiredThrottle(correctedThrottleValue, false);
647 #ifdef USE_FW_AUTOLAND
648 // Advanced autoland
649 if (posControl.navState == NAV_STATE_FW_LANDING_GLIDE || posControl.navState == NAV_STATE_FW_LANDING_FLARE || STATE(LANDING_DETECTED)) {
650 // Set motor to min. throttle and stop it when MOTOR_STOP feature is enabled
651 ENABLE_STATE(NAV_MOTOR_STOP_OR_IDLE);
653 if (posControl.navState == NAV_STATE_FW_LANDING_GLIDE) {
654 rcCommand[PITCH] = pidAngleToRcCommand(-DEGREES_TO_DECIDEGREES(navFwAutolandConfig()->glidePitch), pidProfile()->max_angle_inclination[FD_PITCH]);
657 if (posControl.navState == NAV_STATE_FW_LANDING_FLARE) {
658 rcCommand[PITCH] = pidAngleToRcCommand(-DEGREES_TO_DECIDEGREES(navFwAutolandConfig()->flarePitch), pidProfile()->max_angle_inclination[FD_PITCH]);
661 #endif
662 // "Traditional" landing as fallback option
663 if (navStateFlags & NAV_CTL_LAND) {
664 int32_t finalAltitude = navConfig()->general.land_slowdown_minalt + posControl.rthState.homeTmpWaypoint.z;
666 if ((posControl.flags.estAltStatus >= EST_USABLE && navGetCurrentActualPositionAndVelocity()->pos.z <= finalAltitude) ||
667 (posControl.flags.estAglStatus == EST_TRUSTED && posControl.actualState.agl.pos.z <= navConfig()->general.land_slowdown_minalt)) {
669 // Set motor to min. throttle and stop it when MOTOR_STOP feature is enabled
670 ENABLE_STATE(NAV_MOTOR_STOP_OR_IDLE);
672 // Stabilize ROLL axis on 0 degrees banking regardless of loiter radius and position
673 rcCommand[ROLL] = 0;
675 // Stabilize PITCH angle into shallow dive as specified by the nav_fw_land_dive_angle setting (default value is 2 - defined in navigation.c).
676 rcCommand[PITCH] = pidAngleToRcCommand(DEGREES_TO_DECIDEGREES(navConfig()->fw.land_dive_angle), pidProfile()->max_angle_inclination[FD_PITCH]);
681 bool isFixedWingAutoThrottleManuallyIncreased(void)
683 return isAutoThrottleManuallyIncreased;
686 bool isFixedWingFlying(void)
688 float airspeed = 0.0f;
689 #ifdef USE_PITOT
690 if (sensors(SENSOR_PITOT) && pitotIsHealthy()) {
691 airspeed = getAirspeedEstimate();
693 #endif
694 bool throttleCondition = getMotorCount() == 0 || rcCommand[THROTTLE] > currentBatteryProfile->nav.fw.cruise_throttle;
695 bool velCondition = posControl.actualState.velXY > 250.0f || airspeed > 250.0f;
696 bool launchCondition = isNavLaunchEnabled() && fixedWingLaunchStatus() == FW_LAUNCH_FLYING;
698 return (isGPSHeadingValid() && throttleCondition && velCondition) || launchCondition;
701 /*-----------------------------------------------------------
702 * FixedWing land detector
703 *-----------------------------------------------------------*/
704 bool isFixedWingLandingDetected(void)
706 DEBUG_SET(DEBUG_LANDING, 4, 0);
707 static bool fixAxisCheck = false;
709 // Basic condition to start looking for landing
710 bool startCondition = (navGetCurrentStateFlags() & (NAV_CTL_LAND | NAV_CTL_EMERG))
711 || FLIGHT_MODE(FAILSAFE_MODE)
712 || FLIGHT_MODE(NAV_FW_AUTOLAND)
713 || (!navigationIsControllingThrottle() && throttleStickIsLow());
715 if (!startCondition || posControl.flags.resetLandingDetector) {
716 return fixAxisCheck = posControl.flags.resetLandingDetector = false;
718 DEBUG_SET(DEBUG_LANDING, 4, 1);
720 static timeMs_t fwLandingTimerStartAt;
721 static int16_t fwLandSetRollDatum;
722 static int16_t fwLandSetPitchDatum;
723 const float sensitivity = navConfig()->general.land_detect_sensitivity / 5.0f;
725 const timeMs_t currentTimeMs = millis();
727 // Check horizontal and vertical velocities are low (cm/s)
728 bool velCondition = fabsf(navGetCurrentActualPositionAndVelocity()->vel.z) < (50.0f * sensitivity) &&
729 ( posControl.actualState.velXY < (100.0f * sensitivity));
730 // Check angular rates are low (degs/s)
731 bool gyroCondition = averageAbsGyroRates() < (2.0f * sensitivity);
732 DEBUG_SET(DEBUG_LANDING, 2, velCondition);
733 DEBUG_SET(DEBUG_LANDING, 3, gyroCondition);
735 if (velCondition && gyroCondition){
736 DEBUG_SET(DEBUG_LANDING, 4, 2);
737 DEBUG_SET(DEBUG_LANDING, 5, fixAxisCheck);
738 if (!fixAxisCheck) { // capture roll and pitch angles to be used as datums to check for absolute change
739 fwLandSetRollDatum = attitude.values.roll; //0.1 deg increments
740 fwLandSetPitchDatum = attitude.values.pitch;
741 fixAxisCheck = true;
742 fwLandingTimerStartAt = currentTimeMs;
743 } else {
744 const uint8_t angleLimit = 5 * sensitivity;
745 bool isRollAxisStatic = ABS(fwLandSetRollDatum - attitude.values.roll) < angleLimit;
746 bool isPitchAxisStatic = ABS(fwLandSetPitchDatum - attitude.values.pitch) < angleLimit;
747 DEBUG_SET(DEBUG_LANDING, 6, isRollAxisStatic);
748 DEBUG_SET(DEBUG_LANDING, 7, isPitchAxisStatic);
749 if (isRollAxisStatic && isPitchAxisStatic) {
750 /* Probably landed, low horizontal and vertical velocities and no axis rotation in Roll and Pitch
751 * Conditions need to be held for fixed safety time + optional extra delay.
752 * Fixed time increased if velocities invalid to provide extra safety margin against false triggers */
753 const uint16_t safetyTime = posControl.flags.estAltStatus == EST_NONE || posControl.flags.estVelStatus == EST_NONE ? 5000 : 1000;
754 timeMs_t safetyTimeDelay = safetyTime + navConfig()->general.auto_disarm_delay;
755 return currentTimeMs - fwLandingTimerStartAt > safetyTimeDelay;
756 } else {
757 fixAxisCheck = false;
761 return false;
764 /*-----------------------------------------------------------
765 * FixedWing emergency landing
766 *-----------------------------------------------------------*/
767 void applyFixedWingEmergencyLandingController(timeUs_t currentTimeUs)
769 rcCommand[THROTTLE] = setDesiredThrottle(currentBatteryProfile->failsafe_throttle, true);
771 if (posControl.flags.estAltStatus >= EST_USABLE) {
772 // target min descent rate at distance 2 x emerg descent rate above takeoff altitude
773 updateClimbRateToAltitudeController(0, 2.0f * navConfig()->general.emerg_descent_rate, ROC_TO_ALT_TARGET);
774 applyFixedWingAltitudeAndThrottleController(currentTimeUs);
776 int16_t pitchCorrection = constrain(posControl.rcAdjustment[PITCH], -DEGREES_TO_DECIDEGREES(navConfig()->fw.max_dive_angle), DEGREES_TO_DECIDEGREES(navConfig()->fw.max_climb_angle));
777 rcCommand[PITCH] = -pidAngleToRcCommand(pitchCorrection, pidProfile()->max_angle_inclination[FD_PITCH]);
778 } else {
779 rcCommand[PITCH] = pidAngleToRcCommand(failsafeConfig()->failsafe_fw_pitch_angle, pidProfile()->max_angle_inclination[FD_PITCH]);
782 if (posControl.flags.estPosStatus >= EST_USABLE) { // Hold position if possible
783 applyFixedWingPositionController(currentTimeUs);
784 int16_t rollCorrection = constrain(posControl.rcAdjustment[ROLL],
785 -DEGREES_TO_DECIDEGREES(navConfig()->fw.max_bank_angle),
786 DEGREES_TO_DECIDEGREES(navConfig()->fw.max_bank_angle));
787 rcCommand[ROLL] = pidAngleToRcCommand(rollCorrection, pidProfile()->max_angle_inclination[FD_ROLL]);
788 rcCommand[YAW] = 0;
789 } else {
790 rcCommand[ROLL] = pidAngleToRcCommand(failsafeConfig()->failsafe_fw_roll_angle, pidProfile()->max_angle_inclination[FD_ROLL]);
791 rcCommand[YAW] = -pidRateToRcCommand(failsafeConfig()->failsafe_fw_yaw_rate, currentControlRateProfile->stabilized.rates[FD_YAW]);
795 /*-----------------------------------------------------------
796 * Calculate loiter target based on current position and velocity
797 *-----------------------------------------------------------*/
798 void calculateFixedWingInitialHoldPosition(fpVector3_t * pos)
800 // TODO: stub, this should account for velocity and target loiter radius
801 *pos = navGetCurrentActualPositionAndVelocity()->pos;
804 void resetFixedWingHeadingController(void)
806 updateHeadingHoldTarget(CENTIDEGREES_TO_DEGREES(posControl.actualState.cog));
809 void applyFixedWingNavigationController(navigationFSMStateFlags_t navStateFlags, timeUs_t currentTimeUs)
811 if (navStateFlags & NAV_CTL_LAUNCH) {
812 applyFixedWingLaunchController(currentTimeUs);
814 else if (navStateFlags & NAV_CTL_EMERG) {
815 applyFixedWingEmergencyLandingController(currentTimeUs);
817 else {
818 #ifdef NAV_FW_LIMIT_MIN_FLY_VELOCITY
819 // Don't apply anything if ground speed is too low (<3m/s)
820 if (posControl.actualState.velXY > 300) {
821 #else
822 if (true) {
823 #endif
824 if (navStateFlags & NAV_CTL_ALT) {
825 if (getMotorStatus() == MOTOR_STOPPED_USER || FLIGHT_MODE(SOARING_MODE)) {
826 // Motor has been stopped by user or soaring mode enabled to override altitude control
827 resetFixedWingAltitudeController();
828 setDesiredPosition(&navGetCurrentActualPositionAndVelocity()->pos, posControl.actualState.yaw, NAV_POS_UPDATE_Z);
829 } else {
830 applyFixedWingAltitudeAndThrottleController(currentTimeUs);
834 if (navStateFlags & NAV_CTL_POS) {
835 applyFixedWingPositionController(currentTimeUs);
838 } else {
839 posControl.rcAdjustment[PITCH] = 0;
840 posControl.rcAdjustment[ROLL] = 0;
843 if (FLIGHT_MODE(NAV_COURSE_HOLD_MODE) && posControl.flags.isAdjustingPosition) {
844 rcCommand[ROLL] = applyDeadbandRescaled(rcCommand[ROLL], rcControlsConfig()->pos_hold_deadband, -500, 500);
847 //if (navStateFlags & NAV_CTL_YAW)
848 if ((navStateFlags & NAV_CTL_ALT) || (navStateFlags & NAV_CTL_POS)) {
849 applyFixedWingPitchRollThrottleController(navStateFlags, currentTimeUs);
852 if (FLIGHT_MODE(SOARING_MODE) && navConfig()->general.flags.soaring_motor_stop) {
853 ENABLE_STATE(NAV_MOTOR_STOP_OR_IDLE);
858 float navigationGetCrossTrackError(void)
860 return navCrossTrackError;