/* Lead developer: Andrew Tridgell Authors: Doug Weibel, Jose Julio, Jordi Munoz, Jason Short, Randy Mackay, Pat Hickey, John Arne Birkeland, Olivier Adler, Amilcar Lucas, Gregory Fletcher, Paul Riseborough, Brandon Jones, Jon Challinger, Tom Pittenger Thanks to: Chris Anderson, Michael Oborne, Paul Mather, Bill Premerlani, James Cohen, JB from rotorFX, Automatik, Fefenin, Peter Meister, Remzibi, Yury Smirnov, Sandro Benigno, Max Levine, Roberto Navoni, Lorenz Meier, Yury MonZon Please contribute your ideas! See https://ardupilot.org/dev for details 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, see . */ #include "Plane.h" #define SCHED_TASK(func, rate_hz, max_time_micros, priority) SCHED_TASK_CLASS(Plane, &plane, func, rate_hz, max_time_micros, priority) #define FAST_TASK(func) FAST_TASK_CLASS(Plane, &plane, func) /* scheduler table - all regular tasks should be listed here. All entries in this table must be ordered by priority. This table is interleaved with the table presnet in each of the vehicles to determine the order in which tasks are run. Convenience methods SCHED_TASK and SCHED_TASK_CLASS are provided to build entries in this structure: SCHED_TASK arguments: - name of static function to call - rate (in Hertz) at which the function should be called - expected time (in MicroSeconds) that the function should take to run - priority (0 through 255, lower number meaning higher priority) SCHED_TASK_CLASS arguments: - class name of method to be called - instance on which to call the method - method to call on that instance - rate (in Hertz) at which the method should be called - expected time (in MicroSeconds) that the method should take to run - priority (0 through 255, lower number meaning higher priority) FAST_TASK entries are run on every loop even if that means the loop overruns its allotted time */ const AP_Scheduler::Task Plane::scheduler_tasks[] = { // Units: Hz us FAST_TASK(ahrs_update), FAST_TASK(update_control_mode), FAST_TASK(stabilize), FAST_TASK(set_servos), SCHED_TASK(read_radio, 50, 100, 6), SCHED_TASK(check_short_failsafe, 50, 100, 9), SCHED_TASK(update_speed_height, 50, 200, 12), SCHED_TASK(update_throttle_hover, 100, 90, 24), SCHED_TASK_CLASS(RC_Channels, (RC_Channels*)&plane.g2.rc_channels, read_mode_switch, 7, 100, 27), SCHED_TASK(update_GPS_50Hz, 50, 300, 30), SCHED_TASK(update_GPS_10Hz, 10, 400, 33), SCHED_TASK(navigate, 10, 150, 36), SCHED_TASK(update_compass, 10, 200, 39), SCHED_TASK(calc_airspeed_errors, 10, 100, 42), SCHED_TASK(update_alt, 10, 200, 45), SCHED_TASK(adjust_altitude_target, 10, 200, 48), #if AP_ADVANCEDFAILSAFE_ENABLED SCHED_TASK(afs_fs_check, 10, 100, 51), #endif SCHED_TASK(ekf_check, 10, 75, 54), SCHED_TASK_CLASS(GCS, (GCS*)&plane._gcs, update_receive, 300, 500, 57), SCHED_TASK_CLASS(GCS, (GCS*)&plane._gcs, update_send, 300, 750, 60), #if AP_SERVORELAYEVENTS_ENABLED SCHED_TASK_CLASS(AP_ServoRelayEvents, &plane.ServoRelayEvents, update_events, 50, 150, 63), #endif SCHED_TASK_CLASS(AP_BattMonitor, &plane.battery, read, 10, 300, 66), SCHED_TASK(read_rangefinder, 50, 100, 78), #if AP_ICENGINE_ENABLED SCHED_TASK_CLASS(AP_ICEngine, &plane.g2.ice_control, update, 10, 100, 81), #endif #if AP_OPTICALFLOW_ENABLED SCHED_TASK_CLASS(AP_OpticalFlow, &plane.optflow, update, 50, 50, 87), #endif SCHED_TASK(one_second_loop, 1, 400, 90), SCHED_TASK(three_hz_loop, 3, 75, 93), SCHED_TASK(check_long_failsafe, 3, 400, 96), #if AP_RPM_ENABLED SCHED_TASK_CLASS(AP_RPM, &plane.rpm_sensor, update, 10, 100, 99), #endif #if AP_AIRSPEED_AUTOCAL_ENABLE SCHED_TASK(airspeed_ratio_update, 1, 100, 102), #endif // AP_AIRSPEED_AUTOCAL_ENABLE #if HAL_MOUNT_ENABLED SCHED_TASK_CLASS(AP_Mount, &plane.camera_mount, update, 50, 100, 105), #endif // HAL_MOUNT_ENABLED #if AP_CAMERA_ENABLED SCHED_TASK_CLASS(AP_Camera, &plane.camera, update, 50, 100, 108), #endif // CAMERA == ENABLED #if HAL_LOGGING_ENABLED SCHED_TASK_CLASS(AP_Scheduler, &plane.scheduler, update_logging, 0.2, 100, 111), #endif SCHED_TASK(compass_save, 0.1, 200, 114), #if HAL_LOGGING_ENABLED SCHED_TASK(Log_Write_FullRate, 400, 300, 117), SCHED_TASK(update_logging10, 10, 300, 120), SCHED_TASK(update_logging25, 25, 300, 123), #endif #if HAL_SOARING_ENABLED SCHED_TASK(update_soaring, 50, 400, 126), #endif SCHED_TASK(parachute_check, 10, 200, 129), #if AP_TERRAIN_AVAILABLE SCHED_TASK_CLASS(AP_Terrain, &plane.terrain, update, 10, 200, 132), #endif // AP_TERRAIN_AVAILABLE SCHED_TASK(update_is_flying_5Hz, 5, 100, 135), #if HAL_LOGGING_ENABLED SCHED_TASK_CLASS(AP_Logger, &plane.logger, periodic_tasks, 50, 400, 138), #endif SCHED_TASK_CLASS(AP_InertialSensor, &plane.ins, periodic, 50, 50, 141), #if HAL_ADSB_ENABLED SCHED_TASK(avoidance_adsb_update, 10, 100, 144), #endif SCHED_TASK_CLASS(RC_Channels, (RC_Channels*)&plane.g2.rc_channels, read_aux_all, 10, 200, 147), #if HAL_BUTTON_ENABLED SCHED_TASK_CLASS(AP_Button, &plane.button, update, 5, 100, 150), #endif #if AP_LANDINGGEAR_ENABLED SCHED_TASK(landing_gear_update, 5, 50, 159), #endif #if AC_PRECLAND_ENABLED SCHED_TASK(precland_update, 400, 50, 160), #endif }; void Plane::get_scheduler_tasks(const AP_Scheduler::Task *&tasks, uint8_t &task_count, uint32_t &log_bit) { tasks = &scheduler_tasks[0]; task_count = ARRAY_SIZE(scheduler_tasks); log_bit = MASK_LOG_PM; } #if HAL_QUADPLANE_ENABLED constexpr int8_t Plane::_failsafe_priorities[7]; #else constexpr int8_t Plane::_failsafe_priorities[6]; #endif // update AHRS system void Plane::ahrs_update() { arming.update_soft_armed(); ahrs.update(); #if HAL_LOGGING_ENABLED if (should_log(MASK_LOG_IMU)) { AP::ins().Write_IMU(); } #endif // calculate a scaled roll limit based on current pitch roll_limit_cd = aparm.roll_limit*100; pitch_limit_min = aparm.pitch_limit_min; bool rotate_limits = true; #if HAL_QUADPLANE_ENABLED if (quadplane.tailsitter.active()) { rotate_limits = false; } #endif if (rotate_limits) { roll_limit_cd *= ahrs.cos_pitch(); pitch_limit_min *= fabsf(ahrs.cos_roll()); } // updated the summed gyro used for ground steering and // auto-takeoff. Dot product of DCM.c with gyro vector gives earth // frame yaw rate steer_state.locked_course_err += ahrs.get_yaw_rate_earth() * G_Dt; steer_state.locked_course_err = wrap_PI(steer_state.locked_course_err); #if HAL_QUADPLANE_ENABLED // check if we have had a yaw reset from the EKF quadplane.check_yaw_reset(); // update inertial_nav for quadplane quadplane.inertial_nav.update(); #endif #if HAL_LOGGING_ENABLED if (should_log(MASK_LOG_VIDEO_STABILISATION)) { ahrs.write_video_stabilisation(); } #endif } /* update 50Hz speed/height controller */ void Plane::update_speed_height(void) { bool should_run_tecs = control_mode->does_auto_throttle(); #if HAL_QUADPLANE_ENABLED if (quadplane.should_disable_TECS()) { should_run_tecs = false; } #endif if (should_run_tecs) { // Call TECS 50Hz update. Note that we call this regardless of // throttle suppressed, as this needs to be running for // takeoff detection TECS_controller.update_50hz(); } #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_mode() || quadplane.in_assisted_flight()) { quadplane.update_throttle_mix(); } #endif } /* read and update compass */ void Plane::update_compass(void) { compass.read(); } #if HAL_LOGGING_ENABLED /* do 10Hz logging */ void Plane::update_logging10(void) { bool log_faster = (should_log(MASK_LOG_ATTITUDE_FULLRATE) || should_log(MASK_LOG_ATTITUDE_FAST)); if (should_log(MASK_LOG_ATTITUDE_MED) && !log_faster) { Log_Write_Attitude(); ahrs.Write_AOA_SSA(); } else if (log_faster) { ahrs.Write_AOA_SSA(); } #if HAL_MOUNT_ENABLED if (should_log(MASK_LOG_CAMERA)) { camera_mount.write_log(); } #endif } /* do 25Hz logging */ void Plane::update_logging25(void) { // MASK_LOG_ATTITUDE_FULLRATE logs at 400Hz, MASK_LOG_ATTITUDE_FAST at 25Hz, MASK_LOG_ATTIUDE_MED logs at 10Hz // highest rate selected wins bool log_faster = should_log(MASK_LOG_ATTITUDE_FULLRATE); if (should_log(MASK_LOG_ATTITUDE_FAST) && !log_faster) { Log_Write_Attitude(); } if (should_log(MASK_LOG_CTUN)) { Log_Write_Control_Tuning(); #if AP_INERTIALSENSOR_HARMONICNOTCH_ENABLED if (!should_log(MASK_LOG_NOTCH_FULLRATE)) { AP::ins().write_notch_log_messages(); } #endif #if HAL_GYROFFT_ENABLED gyro_fft.write_log_messages(); #endif } if (should_log(MASK_LOG_NTUN)) { Log_Write_Nav_Tuning(); Log_Write_Guided(); } if (should_log(MASK_LOG_RC)) Log_Write_RC(); if (should_log(MASK_LOG_IMU)) AP::ins().Write_Vibration(); } #endif // HAL_LOGGING_ENABLED /* check for AFS failsafe check */ #if AP_ADVANCEDFAILSAFE_ENABLED void Plane::afs_fs_check(void) { afs.check(failsafe.AFS_last_valid_rc_ms); } #endif #if HAL_WITH_IO_MCU #include extern AP_IOMCU iomcu; #endif void Plane::one_second_loop() { // make it possible to change control channel ordering at runtime set_control_channels(); #if HAL_WITH_IO_MCU iomcu.setup_mixing(&rcmap, g.override_channel.get(), g.mixing_gain, g2.manual_rc_mask); #endif #if HAL_ADSB_ENABLED adsb.set_stall_speed_cm(aparm.airspeed_min * 100); // convert m/s to cm/s adsb.set_max_speed(aparm.airspeed_max); #endif if (flight_option_enabled(FlightOptions::ENABLE_DEFAULT_AIRSPEED)) { // use average of min and max airspeed as default airspeed fusion with high variance ahrs.writeDefaultAirSpeed((float)((aparm.airspeed_min + aparm.airspeed_max)/2), (float)((aparm.airspeed_max - aparm.airspeed_min)/2)); } // sync MAVLink system ID mavlink_system.sysid = g.sysid_this_mav; SRV_Channels::enable_aux_servos(); // update notify flags AP_Notify::flags.pre_arm_check = arming.pre_arm_checks(false); AP_Notify::flags.pre_arm_gps_check = true; AP_Notify::flags.armed = arming.is_armed() || arming.arming_required() == AP_Arming::Required::NO; #if AP_TERRAIN_AVAILABLE && HAL_LOGGING_ENABLED if (should_log(MASK_LOG_GPS)) { terrain.log_terrain_data(); } #endif // update home position if NOT armed and gps position has // changed. Update every 5s at most if (!arming.is_armed() && gps.last_message_time_ms() - last_home_update_ms > 5000 && gps.status() >= AP_GPS::GPS_OK_FIX_3D) { last_home_update_ms = gps.last_message_time_ms(); update_home(); // reset the landing altitude correction landing.alt_offset = 0; } // this ensures G_Dt is correct, catching startup issues with constructors // calling the scheduler methods if (!is_equal(1.0f/scheduler.get_loop_rate_hz(), scheduler.get_loop_period_s()) || !is_equal(G_Dt, scheduler.get_loop_period_s())) { INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); } const float loop_rate = AP::scheduler().get_filtered_loop_rate_hz(); #if HAL_QUADPLANE_ENABLED if (quadplane.available()) { quadplane.attitude_control->set_notch_sample_rate(loop_rate); } #endif rollController.set_notch_sample_rate(loop_rate); pitchController.set_notch_sample_rate(loop_rate); yawController.set_notch_sample_rate(loop_rate); } void Plane::three_hz_loop() { #if AP_FENCE_ENABLED fence_check(); #endif } void Plane::compass_save() { if (AP::compass().available() && compass.get_learn_type() >= Compass::LEARN_INTERNAL && !hal.util->get_soft_armed()) { /* only save offsets when disarmed */ compass.save_offsets(); } } #if AP_AIRSPEED_AUTOCAL_ENABLE /* once a second update the airspeed calibration ratio */ void Plane::airspeed_ratio_update(void) { if (!airspeed.enabled() || gps.status() < AP_GPS::GPS_OK_FIX_3D || gps.ground_speed() < 4) { // don't calibrate when not moving return; } if (airspeed.get_airspeed() < aparm.airspeed_min && gps.ground_speed() < (uint32_t)aparm.airspeed_min) { // don't calibrate when flying below the minimum airspeed. We // check both airspeed and ground speed to catch cases where // the airspeed ratio is way too low, which could lead to it // never coming up again return; } if (labs(ahrs.roll_sensor) > roll_limit_cd || ahrs.pitch_sensor > aparm.pitch_limit_max*100 || ahrs.pitch_sensor < pitch_limit_min*100) { // don't calibrate when going beyond normal flight envelope return; } const Vector3f &vg = gps.velocity(); airspeed.update_calibration(vg, aparm.airspeed_max); } #endif // AP_AIRSPEED_AUTOCAL_ENABLE /* read the GPS and update position */ void Plane::update_GPS_50Hz(void) { gps.update(); update_current_loc(); } /* read update GPS position - 10Hz update */ void Plane::update_GPS_10Hz(void) { static uint32_t last_gps_msg_ms; if (gps.last_message_time_ms() != last_gps_msg_ms && gps.status() >= AP_GPS::GPS_OK_FIX_3D) { last_gps_msg_ms = gps.last_message_time_ms(); if (ground_start_count > 1) { ground_start_count--; } else if (ground_start_count == 1) { // We countdown N number of good GPS fixes // so that the altitude is more accurate // ------------------------------------- if (current_loc.lat == 0 && current_loc.lng == 0) { ground_start_count = 5; } else if (!hal.util->was_watchdog_reset()) { if (!set_home_persistently(gps.location())) { // silently ignore failure... } next_WP_loc = prev_WP_loc = home; ground_start_count = 0; } } // update wind estimate ahrs.estimate_wind(); } else if (gps.status() < AP_GPS::GPS_OK_FIX_3D && ground_start_count != 0) { // lost 3D fix, start again ground_start_count = 5; } calc_gndspeed_undershoot(); } /* main control mode dependent update code */ void Plane::update_control_mode(void) { if (control_mode != &mode_auto) { // hold_course is only used in takeoff and landing steer_state.hold_course_cd = -1; } update_fly_forward(); control_mode->update(); } void Plane::update_fly_forward(void) { // ensure we are fly-forward when we are flying as a pure fixed // wing aircraft. This helps the EKF produce better state // estimates as it can make stronger assumptions #if HAL_QUADPLANE_ENABLED if (quadplane.available() && quadplane.tailsitter.is_in_fw_flight()) { ahrs.set_fly_forward(true); return; } if (quadplane.in_vtol_mode() || quadplane.in_assisted_flight()) { ahrs.set_fly_forward(false); return; } #endif if (flight_stage == AP_FixedWing::FlightStage::LAND) { ahrs.set_fly_forward(landing.is_flying_forward()); return; } ahrs.set_fly_forward(true); } /* set the flight stage */ void Plane::set_flight_stage(AP_FixedWing::FlightStage fs) { if (fs == flight_stage) { return; } landing.handle_flight_stage_change(fs == AP_FixedWing::FlightStage::LAND); if (fs == AP_FixedWing::FlightStage::ABORT_LANDING) { gcs().send_text(MAV_SEVERITY_NOTICE, "Landing aborted, climbing to %dm", int(auto_state.takeoff_altitude_rel_cm/100)); } flight_stage = fs; #if HAL_LOGGING_ENABLED Log_Write_Status(); #endif } void Plane::update_alt() { barometer.update(); // calculate the sink rate. float sink_rate; Vector3f vel; if (ahrs.get_velocity_NED(vel)) { sink_rate = vel.z; } else if (gps.status() >= AP_GPS::GPS_OK_FIX_3D && gps.have_vertical_velocity()) { sink_rate = gps.velocity().z; } else { sink_rate = -barometer.get_climb_rate(); } // low pass the sink rate to take some of the noise out auto_state.sink_rate = 0.8f * auto_state.sink_rate + 0.2f*sink_rate; #if PARACHUTE == ENABLED parachute.set_sink_rate(auto_state.sink_rate); #endif update_flight_stage(); #if AP_SCRIPTING_ENABLED if (nav_scripting_active()) { // don't call TECS while we are in a trick return; } #endif bool should_run_tecs = control_mode->does_auto_throttle(); #if HAL_QUADPLANE_ENABLED if (quadplane.should_disable_TECS()) { should_run_tecs = false; } #endif if (should_run_tecs && !throttle_suppressed) { float distance_beyond_land_wp = 0; if (flight_stage == AP_FixedWing::FlightStage::LAND && current_loc.past_interval_finish_line(prev_WP_loc, next_WP_loc)) { distance_beyond_land_wp = current_loc.get_distance(next_WP_loc); } tecs_target_alt_cm = relative_target_altitude_cm(); if (control_mode == &mode_rtl && !rtl.done_climb && (g2.rtl_climb_min > 0 || (plane.flight_option_enabled(FlightOptions::CLIMB_BEFORE_TURN)))) { // ensure we do the initial climb in RTL. We add an extra // 10m in the demanded height to push TECS to climb // quickly tecs_target_alt_cm = MAX(tecs_target_alt_cm, prev_WP_loc.alt - home.alt) + (g2.rtl_climb_min+10)*100; } TECS_controller.update_pitch_throttle(tecs_target_alt_cm, target_airspeed_cm, flight_stage, distance_beyond_land_wp, get_takeoff_pitch_min_cd(), throttle_nudge, tecs_hgt_afe(), aerodynamic_load_factor, g.pitch_trim.get()); } } /* recalculate the flight_stage */ void Plane::update_flight_stage(void) { // Update the speed & height controller states if (control_mode->does_auto_throttle() && !throttle_suppressed) { if (control_mode == &mode_auto) { #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_auto()) { set_flight_stage(AP_FixedWing::FlightStage::VTOL); return; } #endif if (auto_state.takeoff_complete == false) { set_flight_stage(AP_FixedWing::FlightStage::TAKEOFF); return; } else if (mission.get_current_nav_cmd().id == MAV_CMD_NAV_LAND) { if (landing.is_commanded_go_around() || flight_stage == AP_FixedWing::FlightStage::ABORT_LANDING) { // abort mode is sticky, it must complete while executing NAV_LAND set_flight_stage(AP_FixedWing::FlightStage::ABORT_LANDING); } else if (landing.get_abort_throttle_enable() && get_throttle_input() >= 90 && landing.request_go_around()) { gcs().send_text(MAV_SEVERITY_INFO,"Landing aborted via throttle"); set_flight_stage(AP_FixedWing::FlightStage::ABORT_LANDING); } else { set_flight_stage(AP_FixedWing::FlightStage::LAND); } return; } #if HAL_QUADPLANE_ENABLED if (quadplane.in_assisted_flight()) { set_flight_stage(AP_FixedWing::FlightStage::VTOL); return; } #endif set_flight_stage(AP_FixedWing::FlightStage::NORMAL); } else if (control_mode != &mode_takeoff) { // If not in AUTO then assume normal operation for normal TECS operation. // This prevents TECS from being stuck in the wrong stage if you switch from // AUTO to, say, FBWB during a landing, an aborted landing or takeoff. set_flight_stage(AP_FixedWing::FlightStage::NORMAL); } return; } #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_mode() || quadplane.in_assisted_flight()) { set_flight_stage(AP_FixedWing::FlightStage::VTOL); return; } #endif set_flight_stage(AP_FixedWing::FlightStage::NORMAL); } /* If land_DisarmDelay is enabled (non-zero), check for a landing then auto-disarm after time expires only called from AP_Landing, when the landing library is ready to disarm */ void Plane::disarm_if_autoland_complete() { if (landing.get_disarm_delay() > 0 && !is_flying() && arming.arming_required() != AP_Arming::Required::NO && arming.is_armed()) { /* we have auto disarm enabled. See if enough time has passed */ if (millis() - auto_state.last_flying_ms >= landing.get_disarm_delay()*1000UL) { if (arming.disarm(AP_Arming::Method::AUTOLANDED)) { gcs().send_text(MAV_SEVERITY_INFO,"Auto disarmed"); } } } } bool Plane::trigger_land_abort(const float climb_to_alt_m) { if (plane.control_mode != &plane.mode_auto) { return false; } #if HAL_QUADPLANE_ENABLED if (plane.quadplane.in_vtol_auto()) { return quadplane.abort_landing(); } #endif uint16_t mission_id = plane.mission.get_current_nav_cmd().id; bool is_in_landing = (plane.flight_stage == AP_FixedWing::FlightStage::LAND) || plane.is_land_command(mission_id); if (is_in_landing) { // fly a user planned abort pattern if available if (plane.have_position && plane.mission.jump_to_abort_landing_sequence(plane.current_loc)) { return true; } // only fly a fixed wing abort if we aren't doing quadplane stuff, or potentially // shooting a quadplane approach #if HAL_QUADPLANE_ENABLED const bool attempt_go_around = (!plane.quadplane.available()) || ((!plane.quadplane.in_vtol_auto()) && (!plane.quadplane.landing_with_fixed_wing_spiral_approach())); #else const bool attempt_go_around = true; #endif if (attempt_go_around) { // Initiate an aborted landing. This will trigger a pitch-up and // climb-out to a safe altitude holding heading then one of the // following actions will occur, check for in this order: // - If MAV_CMD_CONTINUE_AND_CHANGE_ALT is next command in mission, // increment mission index to execute it // - else if DO_LAND_START is available, jump to it // - else decrement the mission index to repeat the landing approach if (!is_zero(climb_to_alt_m)) { plane.auto_state.takeoff_altitude_rel_cm = climb_to_alt_m * 100; } if (plane.landing.request_go_around()) { plane.auto_state.next_wp_crosstrack = false; return true; } } } return false; } /* the height above field elevation that we pass to TECS */ float Plane::tecs_hgt_afe(void) { /* pass the height above field elevation as the height above the ground when in landing, which means that TECS gets the rangefinder information and thus can know when the flare is coming. */ float hgt_afe; if (flight_stage == AP_FixedWing::FlightStage::LAND) { hgt_afe = height_above_target(); hgt_afe -= rangefinder_correction(); } else { // when in normal flight we pass the hgt_afe as relative // altitude to home hgt_afe = relative_altitude; } return hgt_afe; } // vehicle specific waypoint info helpers bool Plane::get_wp_distance_m(float &distance) const { // see GCS_MAVLINK_Plane::send_nav_controller_output() if (control_mode == &mode_manual) { return false; } #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_mode()) { distance = quadplane.using_wp_nav() ? quadplane.wp_nav->get_wp_distance_to_destination() * 0.01 : 0; return true; } #endif distance = auto_state.wp_distance; return true; } bool Plane::get_wp_bearing_deg(float &bearing) const { // see GCS_MAVLINK_Plane::send_nav_controller_output() if (control_mode == &mode_manual) { return false; } #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_mode()) { bearing = quadplane.using_wp_nav() ? quadplane.wp_nav->get_wp_bearing_to_destination() : 0; return true; } #endif bearing = nav_controller->target_bearing_cd() * 0.01; return true; } bool Plane::get_wp_crosstrack_error_m(float &xtrack_error) const { // see GCS_MAVLINK_Plane::send_nav_controller_output() if (control_mode == &mode_manual) { return false; } #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_mode()) { xtrack_error = quadplane.using_wp_nav() ? quadplane.wp_nav->crosstrack_error() : 0; return true; } #endif xtrack_error = nav_controller->crosstrack_error(); return true; } #if AP_SCRIPTING_ENABLED || AP_EXTERNAL_CONTROL_ENABLED // set target location (for use by external control and scripting) bool Plane::set_target_location(const Location &target_loc) { Location loc{target_loc}; if (plane.control_mode != &plane.mode_guided) { // only accept position updates when in GUIDED mode return false; } // add home alt if needed if (loc.relative_alt) { loc.alt += plane.home.alt; loc.relative_alt = 0; } plane.set_guided_WP(loc); return true; } #endif //AP_SCRIPTING_ENABLED || AP_EXTERNAL_CONTROL_ENABLED #if AP_SCRIPTING_ENABLED // get target location (for use by scripting) bool Plane::get_target_location(Location& target_loc) { switch (control_mode->mode_number()) { case Mode::Number::RTL: case Mode::Number::AVOID_ADSB: case Mode::Number::GUIDED: case Mode::Number::AUTO: case Mode::Number::LOITER: case Mode::Number::TAKEOFF: #if HAL_QUADPLANE_ENABLED case Mode::Number::QLOITER: case Mode::Number::QLAND: case Mode::Number::QRTL: #endif target_loc = next_WP_loc; return true; break; default: break; } return false; } /* update_target_location() works in all auto navigation modes */ bool Plane::update_target_location(const Location &old_loc, const Location &new_loc) { /* by checking the caller has provided the correct old target location we prevent a race condition where the user changes mode or commands a different target in the controlling lua script */ if (!old_loc.same_loc_as(next_WP_loc) || old_loc.get_alt_frame() != new_loc.get_alt_frame()) { return false; } next_WP_loc = new_loc; #if HAL_QUADPLANE_ENABLED if (control_mode == &mode_qland || control_mode == &mode_qloiter) { mode_qloiter.last_target_loc_set_ms = AP_HAL::millis(); } #endif return true; } // allow for velocity matching in VTOL bool Plane::set_velocity_match(const Vector2f &velocity) { #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_mode() || quadplane.in_vtol_land_sequence()) { quadplane.poscontrol.velocity_match = velocity; quadplane.poscontrol.last_velocity_match_ms = AP_HAL::millis(); return true; } #endif return false; } // allow for override of land descent rate bool Plane::set_land_descent_rate(float descent_rate) { #if HAL_QUADPLANE_ENABLED if (quadplane.in_vtol_land_descent() || control_mode == &mode_qland) { quadplane.poscontrol.override_descent_rate = descent_rate; quadplane.poscontrol.last_override_descent_ms = AP_HAL::millis(); return true; } #endif return false; } #endif // AP_SCRIPTING_ENABLED // returns true if vehicle is landing. bool Plane::is_landing() const { #if HAL_QUADPLANE_ENABLED if (plane.quadplane.in_vtol_land_descent()) { return true; } #endif return control_mode->is_landing(); } // returns true if vehicle is taking off. bool Plane::is_taking_off() const { #if HAL_QUADPLANE_ENABLED if (plane.quadplane.in_vtol_takeoff()) { return true; } #endif return control_mode->is_taking_off(); } // correct AHRS pitch for PTCH_TRIM_DEG in non-VTOL modes, and return VTOL view in VTOL void Plane::get_osd_roll_pitch_rad(float &roll, float &pitch) const { #if HAL_QUADPLANE_ENABLED if (quadplane.show_vtol_view()) { pitch = quadplane.ahrs_view->pitch; roll = quadplane.ahrs_view->roll; return; } #endif pitch = ahrs.get_pitch(); roll = ahrs.get_roll(); if (!(flight_option_enabled(FlightOptions::OSD_REMOVE_TRIM_PITCH))) { // correct for PTCH_TRIM_DEG pitch -= g.pitch_trim * DEG_TO_RAD; } } /* update current_loc Location */ void Plane::update_current_loc(void) { have_position = plane.ahrs.get_location(plane.current_loc); // re-calculate relative altitude ahrs.get_relative_position_D_home(plane.relative_altitude); relative_altitude *= -1.0f; } // check if FLIGHT_OPTION is enabled bool Plane::flight_option_enabled(FlightOptions flight_option) const { return g2.flight_options & flight_option; } #if AC_PRECLAND_ENABLED void Plane::precland_update(void) { // alt will be unused if we pass false through as the second parameter: return g2.precland.update(rangefinder_state.height_estimate*100, rangefinder_state.in_range); } #endif AP_HAL_MAIN_CALLBACKS(&plane);