/** ****************************************************************************** * * @file fixedwingpathfollower.c * @author The OpenPilot Team, http://www.openpilot.org Copyright (C) 2010. * @brief This module compared @ref PositionActuatl to @ref ActiveWaypoint * and sets @ref AttitudeDesired. It only does this when the FlightMode field * of @ref ManualControlCommand is Auto. * * @see The GNU Public License (GPL) Version 3 * *****************************************************************************/ /* * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /** * Input object: ActiveWaypoint * Input object: PositionState * Input object: ManualControlCommand * Output object: AttitudeDesired * * This module will periodically update the value of the AttitudeDesired object. * * The module executes in its own thread in this example. * * Modules have no API, all communication to other modules is done through UAVObjects. * However modules may use the API exposed by shared libraries. * See the OpenPilot wiki for more details. * http://www.openpilot.org/OpenPilot_Application_Architecture * */ #include #include "hwsettings.h" #include "attitudestate.h" #include "pathdesired.h" // object that will be updated by the module #include "positionstate.h" #include "manualcontrol.h" #include "flightstatus.h" #include "pathstatus.h" #include "airspeedstate.h" #include "fixedwingpathfollowersettings.h" #include "fixedwingpathfollowerstatus.h" #include "homelocation.h" #include "stabilizationdesired.h" #include "stabilizationsettings.h" #include "systemsettings.h" #include "velocitydesired.h" #include "velocitystate.h" #include "taskinfo.h" #include "paths.h" #include "CoordinateConversions.h" // Private constants #define MAX_QUEUE_SIZE 4 #define STACK_SIZE_BYTES 1548 #define TASK_PRIORITY (tskIDLE_PRIORITY + 2) // Private variables static bool followerEnabled = false; static xTaskHandle pathfollowerTaskHandle; static PathDesiredData pathDesired; static PathStatusData pathStatus; static FixedWingPathFollowerSettingsData fixedwingpathfollowerSettings; // Private functions static void pathfollowerTask(void *parameters); static void SettingsUpdatedCb(UAVObjEvent *ev); static void updatePathVelocity(); static uint8_t updateFixedDesiredAttitude(); static void updateFixedAttitude(); static void airspeedStateUpdatedCb(UAVObjEvent *ev); static float bound(float val, float min, float max); /** * Initialise the module, called on startup * \returns 0 on success or -1 if initialisation failed */ int32_t FixedWingPathFollowerStart() { if (followerEnabled) { // Start main task xTaskCreate(pathfollowerTask, (signed char *)"PathFollower", STACK_SIZE_BYTES / 4, NULL, TASK_PRIORITY, &pathfollowerTaskHandle); PIOS_TASK_MONITOR_RegisterTask(TASKINFO_RUNNING_PATHFOLLOWER, pathfollowerTaskHandle); } return 0; } /** * Initialise the module, called on startup * \returns 0 on success or -1 if initialisation failed */ int32_t FixedWingPathFollowerInitialize() { HwSettingsInitialize(); uint8_t optionalModules[HWSETTINGS_OPTIONALMODULES_NUMELEM]; HwSettingsOptionalModulesGet(optionalModules); if (optionalModules[HWSETTINGS_OPTIONALMODULES_FIXEDWINGPATHFOLLOWER] == HWSETTINGS_OPTIONALMODULES_ENABLED) { followerEnabled = true; FixedWingPathFollowerSettingsInitialize(); FixedWingPathFollowerStatusInitialize(); PathDesiredInitialize(); PathStatusInitialize(); VelocityDesiredInitialize(); AirspeedStateInitialize(); } else { followerEnabled = false; } return 0; } MODULE_INITCALL(FixedWingPathFollowerInitialize, FixedWingPathFollowerStart) static float northVelIntegral = 0; static float eastVelIntegral = 0; static float downVelIntegral = 0; static float bearingIntegral = 0; static float speedIntegral = 0; static float powerIntegral = 0; static float airspeedErrorInt = 0; // correct speed by measured airspeed static float indicatedAirspeedStateBias = 0; /** * Module thread, should not return. */ static void pathfollowerTask(__attribute__((unused)) void *parameters) { SystemSettingsData systemSettings; FlightStatusData flightStatus; portTickType lastUpdateTime; AirspeedStateConnectCallback(airspeedStateUpdatedCb); FixedWingPathFollowerSettingsConnectCallback(SettingsUpdatedCb); PathDesiredConnectCallback(SettingsUpdatedCb); FixedWingPathFollowerSettingsGet(&fixedwingpathfollowerSettings); PathDesiredGet(&pathDesired); // Main task loop lastUpdateTime = xTaskGetTickCount(); while (1) { // Conditions when this runs: // 1. Must have FixedWing type airframe // 2. Flight mode is PositionHold and PathDesired.Mode is Endpoint OR // FlightMode is PathPlanner and PathDesired.Mode is Endpoint or Path SystemSettingsGet(&systemSettings); if ((systemSettings.AirframeType != SYSTEMSETTINGS_AIRFRAMETYPE_FIXEDWING) && (systemSettings.AirframeType != SYSTEMSETTINGS_AIRFRAMETYPE_FIXEDWINGELEVON) && (systemSettings.AirframeType != SYSTEMSETTINGS_AIRFRAMETYPE_FIXEDWINGVTAIL)) { AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_WARNING); vTaskDelay(1000); continue; } // Continue collecting data if not enough time vTaskDelayUntil(&lastUpdateTime, fixedwingpathfollowerSettings.UpdatePeriod / portTICK_RATE_MS); FlightStatusGet(&flightStatus); PathStatusGet(&pathStatus); uint8_t result; // Check the combinations of flightmode and pathdesired mode switch (flightStatus.FlightMode) { case FLIGHTSTATUS_FLIGHTMODE_POSITIONHOLD: case FLIGHTSTATUS_FLIGHTMODE_RETURNTOBASE: if (pathDesired.Mode == PATHDESIRED_MODE_FLYENDPOINT) { updatePathVelocity(); result = updateFixedDesiredAttitude(); if (result) { AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_OK); } else { AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_WARNING); } } else { AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_ERROR); } break; case FLIGHTSTATUS_FLIGHTMODE_PATHPLANNER: pathStatus.UID = pathDesired.UID; pathStatus.Status = PATHSTATUS_STATUS_INPROGRESS; switch (pathDesired.Mode) { case PATHDESIRED_MODE_FLYENDPOINT: case PATHDESIRED_MODE_FLYVECTOR: case PATHDESIRED_MODE_FLYCIRCLERIGHT: case PATHDESIRED_MODE_FLYCIRCLELEFT: updatePathVelocity(); result = updateFixedDesiredAttitude(); if (result) { AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_OK); } else { pathStatus.Status = PATHSTATUS_STATUS_CRITICAL; AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_WARNING); } break; case PATHDESIRED_MODE_FIXEDATTITUDE: updateFixedAttitude(pathDesired.ModeParameters); AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_OK); break; case PATHDESIRED_MODE_DISARMALARM: AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_CRITICAL); break; default: pathStatus.Status = PATHSTATUS_STATUS_CRITICAL; AlarmsSet(SYSTEMALARMS_ALARM_GUIDANCE, SYSTEMALARMS_ALARM_ERROR); break; } break; default: // Be cleaner and get rid of global variables northVelIntegral = 0; eastVelIntegral = 0; downVelIntegral = 0; bearingIntegral = 0; speedIntegral = 0; powerIntegral = 0; break; } PathStatusSet(&pathStatus); } } /** * Compute desired velocity from the current position and path * * Takes in @ref PositionState and compares it to @ref PathDesired * and computes @ref VelocityDesired */ static void updatePathVelocity() { PositionStateData positionState; PositionStateGet(&positionState); VelocityStateData velocityState; VelocityStateGet(&velocityState); // look ahead fixedwingpathfollowerSettings.HeadingFeedForward seconds float cur[3] = { positionState.North + (velocityState.North * fixedwingpathfollowerSettings.HeadingFeedForward), positionState.East + (velocityState.East * fixedwingpathfollowerSettings.HeadingFeedForward), positionState.Down + (velocityState.Down * fixedwingpathfollowerSettings.HeadingFeedForward) }; struct path_status progress; path_progress(pathDesired.Start, pathDesired.End, cur, &progress, pathDesired.Mode); float groundspeed; float altitudeSetpoint; switch (pathDesired.Mode) { case PATHDESIRED_MODE_FLYCIRCLERIGHT: case PATHDESIRED_MODE_DRIVECIRCLERIGHT: case PATHDESIRED_MODE_FLYCIRCLELEFT: case PATHDESIRED_MODE_DRIVECIRCLELEFT: groundspeed = pathDesired.EndingVelocity; altitudeSetpoint = pathDesired.End[2]; break; case PATHDESIRED_MODE_FLYENDPOINT: case PATHDESIRED_MODE_DRIVEENDPOINT: case PATHDESIRED_MODE_FLYVECTOR: case PATHDESIRED_MODE_DRIVEVECTOR: default: groundspeed = pathDesired.StartingVelocity + (pathDesired.EndingVelocity - pathDesired.StartingVelocity) * bound(progress.fractional_progress, 0, 1); altitudeSetpoint = pathDesired.Start[2] + (pathDesired.End[2] - pathDesired.Start[2]) * bound(progress.fractional_progress, 0, 1); break; } // make sure groundspeed is not zero if (groundspeed < 1e-2f) { groundspeed = 1e-2f; } // calculate velocity - can be zero if waypoints are too close VelocityDesiredData velocityDesired; velocityDesired.North = progress.path_direction[0]; velocityDesired.East = progress.path_direction[1]; float error_speed = progress.error * fixedwingpathfollowerSettings.HorizontalPosP; // if a plane is crossing its desired flightpath facing the wrong way (away from flight direction) // it would turn towards the flightpath to get on its desired course. This however would reverse the correction vector // once it crosses the flightpath again, which would make it again turn towards the flightpath (but away from its desired heading) // leading to an S-shape snake course the wrong way // this only happens especially if HorizontalPosP is too high, as otherwise the angle between velocity desired and path_direction won't // turn steep unless there is enough space complete the turn before crossing the flightpath // in this case the plane effectively needs to be turned around // indicators: // difference between correction_direction and velocitystate >90 degrees and // difference between path_direction and velocitystate >90 degrees ( 4th sector, facing away from eerything ) // fix: ignore correction, steer in path direction until the situation has become better (condition doesn't apply anymore) float angle1 = RAD2DEG(atan2f(progress.path_direction[1], progress.path_direction[0]) - atan2f(velocityState.East, velocityState.North)); float angle2 = RAD2DEG(atan2f(progress.correction_direction[1], progress.correction_direction[0]) - atan2f(velocityState.East, velocityState.North)); if (angle1 < -180.0f) { angle1 += 360.0f; } if (angle1 > 180.0f) { angle1 -= 360.0f; } if (angle2 < -180.0f) { angle2 += 360.0f; } if (angle2 > 180.0f) { angle2 -= 360.0f; } if (fabsf(angle1) >= 90.0f && fabsf(angle2) >= 90.0f) { error_speed = 0; } // calculate correction - can also be zero if correction vector is 0 or no error present velocityDesired.North += progress.correction_direction[0] * error_speed; velocityDesired.East += progress.correction_direction[1] * error_speed; // scale to correct length float l = sqrtf(velocityDesired.North * velocityDesired.North + velocityDesired.East * velocityDesired.East); velocityDesired.North *= groundspeed / l; velocityDesired.East *= groundspeed / l; float downError = altitudeSetpoint - positionState.Down; velocityDesired.Down = downError * fixedwingpathfollowerSettings.VerticalPosP; // update pathstatus pathStatus.error = progress.error; pathStatus.fractional_progress = progress.fractional_progress; VelocityDesiredSet(&velocityDesired); } /** * Compute desired attitude from a fixed preset * */ static void updateFixedAttitude(float *attitude) { StabilizationDesiredData stabDesired; StabilizationDesiredGet(&stabDesired); stabDesired.Roll = attitude[0]; stabDesired.Pitch = attitude[1]; stabDesired.Yaw = attitude[2]; stabDesired.Throttle = attitude[3]; stabDesired.StabilizationMode[STABILIZATIONDESIRED_STABILIZATIONMODE_ROLL] = STABILIZATIONDESIRED_STABILIZATIONMODE_ATTITUDE; stabDesired.StabilizationMode[STABILIZATIONDESIRED_STABILIZATIONMODE_PITCH] = STABILIZATIONDESIRED_STABILIZATIONMODE_ATTITUDE; stabDesired.StabilizationMode[STABILIZATIONDESIRED_STABILIZATIONMODE_YAW] = STABILIZATIONDESIRED_STABILIZATIONMODE_RATE; StabilizationDesiredSet(&stabDesired); } /** * Compute desired attitude from the desired velocity * * Takes in @ref NedState which has the acceleration in the * NED frame as the feedback term and then compares the * @ref VelocityState against the @ref VelocityDesired */ static uint8_t updateFixedDesiredAttitude() { uint8_t result = 1; float dT = fixedwingpathfollowerSettings.UpdatePeriod / 1000.0f; // Convert from [ms] to [s] VelocityDesiredData velocityDesired; VelocityStateData velocityState; StabilizationDesiredData stabDesired; AttitudeStateData attitudeState; StabilizationSettingsData stabSettings; FixedWingPathFollowerStatusData fixedwingpathfollowerStatus; AirspeedStateData airspeedState; float groundspeedState; float groundspeedDesired; float indicatedAirspeedState; float indicatedAirspeedDesired; float airspeedError; float pitchCommand; float descentspeedDesired; float descentspeedError; float powerCommand; float bearingError; float bearingCommand; FixedWingPathFollowerStatusGet(&fixedwingpathfollowerStatus); VelocityStateGet(&velocityState); StabilizationDesiredGet(&stabDesired); VelocityDesiredGet(&velocityDesired); AttitudeStateGet(&attitudeState); StabilizationSettingsGet(&stabSettings); AirspeedStateGet(&airspeedState); /** * Compute speed error (required for throttle and pitch) */ // Current ground speed groundspeedState = sqrtf(velocityState.East * velocityState.East + velocityState.North * velocityState.North); // note that airspeedStateBias is ( calibratedAirspeed - groundSpeed ) at the time of measurement, // but thanks to accelerometers, groundspeed reacts faster to changes in direction // than airspeed and gps sensors alone indicatedAirspeedState = groundspeedState + indicatedAirspeedStateBias; // Desired ground speed groundspeedDesired = sqrtf(velocityDesired.North * velocityDesired.North + velocityDesired.East * velocityDesired.East); indicatedAirspeedDesired = bound(groundspeedDesired + indicatedAirspeedStateBias, fixedwingpathfollowerSettings.BestClimbRateSpeed, fixedwingpathfollowerSettings.CruiseSpeed); // Airspeed error airspeedError = indicatedAirspeedDesired - indicatedAirspeedState; // Vertical speed error descentspeedDesired = bound( velocityDesired.Down, -fixedwingpathfollowerSettings.VerticalVelMax, fixedwingpathfollowerSettings.VerticalVelMax); descentspeedError = descentspeedDesired - velocityState.Down; // Error condition: wind speed is higher than maximum allowed speed. We are forced backwards! fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_WIND] = 0; if (groundspeedDesired - indicatedAirspeedStateBias <= 0) { fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_WIND] = 1; result = 0; } // Error condition: plane too slow or too fast fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_HIGHSPEED] = 0; fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_LOWSPEED] = 0; if (indicatedAirspeedState > fixedwingpathfollowerSettings.AirSpeedMax) { fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_OVERSPEED] = 1; result = 0; } if (indicatedAirspeedState > fixedwingpathfollowerSettings.CruiseSpeed * 1.2f) { fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_HIGHSPEED] = 1; result = 0; } if (indicatedAirspeedState < fixedwingpathfollowerSettings.BestClimbRateSpeed * 0.8f && 1) { // The next three && 1 are placeholders for UAVOs representing LANDING and TAKEOFF fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_LOWSPEED] = 1; result = 0; } if (indicatedAirspeedState < fixedwingpathfollowerSettings.StallSpeedClean && 1 && 1) { // Where the && 1 represents the UAVO that will control whether the airplane is prepped for landing or not fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_STALLSPEED] = 1; result = 0; } if (indicatedAirspeedState < fixedwingpathfollowerSettings.StallSpeedDirty && 1) { fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_STALLSPEED] = 1; result = 0; } if (indicatedAirspeedState < 1e-6f) { // prevent division by zero, abort without controlling anything. This guidance mode is not suited for takeoff or touchdown, or handling stationary planes // also we cannot handle planes flying backwards, lets just wait until the nose drops fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_LOWSPEED] = 1; return 0; } /** * Compute desired throttle command */ // compute saturated integral error throttle response. Make integral leaky for better performance. Approximately 30s time constant. if (fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_KI] > 0) { powerIntegral = bound(powerIntegral + -descentspeedError * dT, -fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_ILIMIT] / fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_KI], fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_ILIMIT] / fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_KI] ) * (1.0f - 1.0f / (1.0f + 30.0f / dT)); } else { powerIntegral = 0; } // Compute the cross feed from vertical speed to pitch, with saturation float speedErrorToPowerCommandComponent = bound( (airspeedError / fixedwingpathfollowerSettings.BestClimbRateSpeed) * fixedwingpathfollowerSettings.AirspeedToPowerCrossFeed[FIXEDWINGPATHFOLLOWERSETTINGS_AIRSPEEDTOPOWERCROSSFEED_KP], -fixedwingpathfollowerSettings.AirspeedToPowerCrossFeed[FIXEDWINGPATHFOLLOWERSETTINGS_AIRSPEEDTOPOWERCROSSFEED_MAX], fixedwingpathfollowerSettings.AirspeedToPowerCrossFeed[FIXEDWINGPATHFOLLOWERSETTINGS_AIRSPEEDTOPOWERCROSSFEED_MAX] ); // Compute final throttle response powerCommand = -descentspeedError * fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_KP] + powerIntegral * fixedwingpathfollowerSettings.PowerPI[FIXEDWINGPATHFOLLOWERSETTINGS_POWERPI_KI] + speedErrorToPowerCommandComponent; // Output internal state to telemetry fixedwingpathfollowerStatus.Error[FIXEDWINGPATHFOLLOWERSTATUS_ERROR_POWER] = descentspeedError; fixedwingpathfollowerStatus.ErrorInt[FIXEDWINGPATHFOLLOWERSTATUS_ERRORINT_POWER] = powerIntegral; fixedwingpathfollowerStatus.Command[FIXEDWINGPATHFOLLOWERSTATUS_COMMAND_POWER] = powerCommand; // set throttle stabDesired.Throttle = bound(fixedwingpathfollowerSettings.ThrottleLimit[FIXEDWINGPATHFOLLOWERSETTINGS_THROTTLELIMIT_NEUTRAL] + powerCommand, fixedwingpathfollowerSettings.ThrottleLimit[FIXEDWINGPATHFOLLOWERSETTINGS_THROTTLELIMIT_MIN], fixedwingpathfollowerSettings.ThrottleLimit[FIXEDWINGPATHFOLLOWERSETTINGS_THROTTLELIMIT_MAX]); // Error condition: plane cannot hold altitude at current speed. fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_LOWPOWER] = 0; if (powerCommand >= fixedwingpathfollowerSettings.ThrottleLimit[FIXEDWINGPATHFOLLOWERSETTINGS_THROTTLELIMIT_MAX] && // throttle at maximum velocityState.Down > 0 && // we ARE going down descentspeedDesired < 0 && // we WANT to go up airspeedError > 0) { // we are too slow already fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_LOWPOWER] = 1; result = 0; } // Error condition: plane keeps climbing despite minimum throttle (opposite of above) fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_HIGHPOWER] = 0; if (powerCommand >= fixedwingpathfollowerSettings.ThrottleLimit[FIXEDWINGPATHFOLLOWERSETTINGS_THROTTLELIMIT_MIN] && // throttle at minimum velocityState.Down < 0 && // we ARE going up descentspeedDesired > 0 && // we WANT to go down airspeedError < 0) { // we are too fast already fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_HIGHPOWER] = 1; result = 0; } /** * Compute desired pitch command */ if (fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_KI] > 0) { // Integrate with saturation airspeedErrorInt = bound(airspeedErrorInt + airspeedError * dT, -fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_ILIMIT] / fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_KI], fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_ILIMIT] / fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_KI]); } // Compute the cross feed from vertical speed to pitch, with saturation float verticalSpeedToPitchCommandComponent = bound(-descentspeedError * fixedwingpathfollowerSettings.VerticalToPitchCrossFeed[FIXEDWINGPATHFOLLOWERSETTINGS_VERTICALTOPITCHCROSSFEED_KP], -fixedwingpathfollowerSettings.VerticalToPitchCrossFeed[FIXEDWINGPATHFOLLOWERSETTINGS_VERTICALTOPITCHCROSSFEED_MAX], fixedwingpathfollowerSettings.VerticalToPitchCrossFeed[FIXEDWINGPATHFOLLOWERSETTINGS_VERTICALTOPITCHCROSSFEED_MAX] ); // Compute the pitch command as err*Kp + errInt*Ki + X_feed. pitchCommand = -(airspeedError * fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_KP] + airspeedErrorInt * fixedwingpathfollowerSettings.SpeedPI[FIXEDWINGPATHFOLLOWERSETTINGS_SPEEDPI_KI] ) + verticalSpeedToPitchCommandComponent; fixedwingpathfollowerStatus.Error[FIXEDWINGPATHFOLLOWERSTATUS_ERROR_SPEED] = airspeedError; fixedwingpathfollowerStatus.ErrorInt[FIXEDWINGPATHFOLLOWERSTATUS_ERRORINT_SPEED] = airspeedErrorInt; fixedwingpathfollowerStatus.Command[FIXEDWINGPATHFOLLOWERSTATUS_COMMAND_SPEED] = pitchCommand; stabDesired.Pitch = bound(fixedwingpathfollowerSettings.PitchLimit[FIXEDWINGPATHFOLLOWERSETTINGS_PITCHLIMIT_NEUTRAL] + pitchCommand, fixedwingpathfollowerSettings.PitchLimit[FIXEDWINGPATHFOLLOWERSETTINGS_PITCHLIMIT_MIN], fixedwingpathfollowerSettings.PitchLimit[FIXEDWINGPATHFOLLOWERSETTINGS_PITCHLIMIT_MAX]); // Error condition: high speed dive fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_PITCHCONTROL] = 0; if (pitchCommand >= fixedwingpathfollowerSettings.PitchLimit[FIXEDWINGPATHFOLLOWERSETTINGS_PITCHLIMIT_MAX] && // pitch demand is full up velocityState.Down > 0 && // we ARE going down descentspeedDesired < 0 && // we WANT to go up airspeedError < 0) { // we are too fast already fixedwingpathfollowerStatus.Errors[FIXEDWINGPATHFOLLOWERSTATUS_ERRORS_PITCHCONTROL] = 1; result = 0; } /** * Compute desired roll command */ if (groundspeedDesired > 1e-6f) { bearingError = RAD2DEG(atan2f(velocityDesired.East, velocityDesired.North) - atan2f(velocityState.East, velocityState.North)); } else { // if we are not supposed to move, run in a circle bearingError = -90.0f; } if (bearingError < -180.0f) { bearingError += 360.0f; } if (bearingError > 180.0f) { bearingError -= 360.0f; } bearingIntegral = bound(bearingIntegral + bearingError * dT * fixedwingpathfollowerSettings.BearingPI[FIXEDWINGPATHFOLLOWERSETTINGS_BEARINGPI_KI], -fixedwingpathfollowerSettings.BearingPI[FIXEDWINGPATHFOLLOWERSETTINGS_BEARINGPI_ILIMIT], fixedwingpathfollowerSettings.BearingPI[FIXEDWINGPATHFOLLOWERSETTINGS_BEARINGPI_ILIMIT]); bearingCommand = (bearingError * fixedwingpathfollowerSettings.BearingPI[FIXEDWINGPATHFOLLOWERSETTINGS_BEARINGPI_KP] + bearingIntegral); fixedwingpathfollowerStatus.Error[FIXEDWINGPATHFOLLOWERSTATUS_ERROR_BEARING] = bearingError; fixedwingpathfollowerStatus.ErrorInt[FIXEDWINGPATHFOLLOWERSTATUS_ERRORINT_BEARING] = bearingIntegral; fixedwingpathfollowerStatus.Command[FIXEDWINGPATHFOLLOWERSTATUS_COMMAND_BEARING] = bearingCommand; stabDesired.Roll = bound(fixedwingpathfollowerSettings.RollLimit[FIXEDWINGPATHFOLLOWERSETTINGS_ROLLLIMIT_NEUTRAL] + bearingCommand, fixedwingpathfollowerSettings.RollLimit[FIXEDWINGPATHFOLLOWERSETTINGS_ROLLLIMIT_MIN], fixedwingpathfollowerSettings.RollLimit[FIXEDWINGPATHFOLLOWERSETTINGS_ROLLLIMIT_MAX]); // TODO: find a check to determine loss of directional control. Likely needs some check of derivative /** * Compute desired yaw command */ // TODO implement raw control mode for yaw and base on Accels.Y stabDesired.Yaw = 0; stabDesired.StabilizationMode[STABILIZATIONDESIRED_STABILIZATIONMODE_ROLL] = STABILIZATIONDESIRED_STABILIZATIONMODE_ATTITUDE; stabDesired.StabilizationMode[STABILIZATIONDESIRED_STABILIZATIONMODE_PITCH] = STABILIZATIONDESIRED_STABILIZATIONMODE_ATTITUDE; stabDesired.StabilizationMode[STABILIZATIONDESIRED_STABILIZATIONMODE_YAW] = STABILIZATIONDESIRED_STABILIZATIONMODE_NONE; StabilizationDesiredSet(&stabDesired); FixedWingPathFollowerStatusSet(&fixedwingpathfollowerStatus); return result; } /** * Bound input value between limits */ static float bound(float val, float min, float max) { if (val < min) { val = min; } else if (val > max) { val = max; } return val; } static void SettingsUpdatedCb(__attribute__((unused)) UAVObjEvent *ev) { FixedWingPathFollowerSettingsGet(&fixedwingpathfollowerSettings); PathDesiredGet(&pathDesired); } static void airspeedStateUpdatedCb(__attribute__((unused)) UAVObjEvent *ev) { AirspeedStateData airspeedState; VelocityStateData velocityState; AirspeedStateGet(&airspeedState); VelocityStateGet(&velocityState); float groundspeed = sqrtf(velocityState.East * velocityState.East + velocityState.North * velocityState.North); indicatedAirspeedStateBias = airspeedState.CalibratedAirspeed - groundspeed; // note - we do fly by Indicated Airspeed (== calibrated airspeed) // however since airspeed is updated less often than groundspeed, we use sudden changes to groundspeed to offset the airspeed by the same measurement. }