/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- /* 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 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 http://dev.ardupilot.com 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) FUNCTOR_BIND(&plane, &Plane::func, void) /* scheduler table - all regular tasks are listed here, along with how often they should be called (in 20ms units) and the maximum time they are expected to take (in microseconds) */ const AP_Scheduler::Task Plane::scheduler_tasks[] PROGMEM = { { SCHED_TASK(read_radio), 1, 700 }, // 0 { SCHED_TASK(check_short_failsafe), 1, 1000 }, { SCHED_TASK(ahrs_update), 1, 6400 }, { SCHED_TASK(update_speed_height), 1, 1600 }, { SCHED_TASK(update_flight_mode), 1, 1400 }, { SCHED_TASK(stabilize), 1, 3500 }, { SCHED_TASK(set_servos), 1, 1600 }, { SCHED_TASK(read_control_switch), 7, 1000 }, { SCHED_TASK(gcs_retry_deferred), 1, 1000 }, { SCHED_TASK(update_GPS_50Hz), 1, 2500 }, { SCHED_TASK(update_GPS_10Hz), 5, 2500 }, // 10 { SCHED_TASK(navigate), 5, 3000 }, { SCHED_TASK(update_compass), 5, 1200 }, { SCHED_TASK(read_airspeed), 5, 1200 }, { SCHED_TASK(update_alt), 5, 3400 }, { SCHED_TASK(adjust_altitude_target), 5, 1000 }, { SCHED_TASK(obc_fs_check), 5, 1000 }, { SCHED_TASK(gcs_update), 1, 1700 }, { SCHED_TASK(gcs_data_stream_send), 1, 3000 }, { SCHED_TASK(update_events), 1, 1500 }, // 20 { SCHED_TASK(check_usb_mux), 5, 300 }, { SCHED_TASK(read_battery), 5, 1000 }, { SCHED_TASK(compass_accumulate), 1, 1500 }, { SCHED_TASK(barometer_accumulate), 1, 900 }, { SCHED_TASK(update_notify), 1, 300 }, { SCHED_TASK(read_rangefinder), 1, 500 }, #if OPTFLOW == ENABLED { SCHED_TASK(update_optical_flow), 1, 500 }, #endif { SCHED_TASK(one_second_loop), 50, 1000 }, { SCHED_TASK(check_long_failsafe), 15, 1000 }, { SCHED_TASK(read_receiver_rssi), 5, 1000 }, { SCHED_TASK(airspeed_ratio_update), 50, 1000 }, // 30 { SCHED_TASK(update_mount), 1, 1500 }, { SCHED_TASK(log_perf_info), 500, 1000 }, { SCHED_TASK(compass_save), 3000, 2500 }, { SCHED_TASK(update_logging1), 5, 1700 }, { SCHED_TASK(update_logging2), 5, 1700 }, #if FRSKY_TELEM_ENABLED == ENABLED { SCHED_TASK(frsky_telemetry_send), 10, 100 }, #endif { SCHED_TASK(terrain_update), 5, 500 }, }; void Plane::setup() { cliSerial = hal.console; // load the default values of variables listed in var_info[] AP_Param::setup_sketch_defaults(); AP_Notify::flags.failsafe_battery = false; notify.init(false); rssi_analog_source = hal.analogin->channel(ANALOG_INPUT_NONE); init_ardupilot(); // initialise the main loop scheduler scheduler.init(&scheduler_tasks[0], ARRAY_SIZE(scheduler_tasks)); } void Plane::loop() { // wait for an INS sample ins.wait_for_sample(); uint32_t timer = micros(); delta_us_fast_loop = timer - fast_loopTimer_us; G_Dt = delta_us_fast_loop * 1.0e-6f; if (delta_us_fast_loop > G_Dt_max && fast_loopTimer_us != 0) { G_Dt_max = delta_us_fast_loop; } if (delta_us_fast_loop < G_Dt_min || G_Dt_min == 0) { G_Dt_min = delta_us_fast_loop; } fast_loopTimer_us = timer; mainLoop_count++; // tell the scheduler one tick has passed scheduler.tick(); // run all the tasks that are due to run. Note that we only // have to call this once per loop, as the tasks are scheduled // in multiples of the main loop tick. So if they don't run on // the first call to the scheduler they won't run on a later // call until scheduler.tick() is called again uint32_t remaining = (timer + 20000) - micros(); if (remaining > 19500) { remaining = 19500; } scheduler.run(remaining); } // update AHRS system void Plane::ahrs_update() { hal.util->set_soft_armed(arming.is_armed() && hal.util->safety_switch_state() != AP_HAL::Util::SAFETY_DISARMED); #if HIL_SUPPORT if (g.hil_mode == 1) { // update hil before AHRS update gcs_update(); } #endif ahrs.update(); if (should_log(MASK_LOG_ATTITUDE_FAST)) { Log_Write_Attitude(); } if (should_log(MASK_LOG_IMU)) { Log_Write_IMU(); #if HAL_CPU_CLASS >= HAL_CPU_CLASS_75 DataFlash.Log_Write_IMUDT(ins); #endif } // calculate a scaled roll limit based on current pitch roll_limit_cd = g.roll_limit_cd * cosf(ahrs.pitch); pitch_limit_min_cd = aparm.pitch_limit_min_cd * fabsf(cosf(ahrs.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); } /* update 50Hz speed/height controller */ void Plane::update_speed_height(void) { if (auto_throttle_mode) { // Call TECS 50Hz update. Note that we call this regardless of // throttle suppressed, as this needs to be running for // takeoff detection SpdHgt_Controller->update_50hz(tecs_hgt_afe()); } } /* update camera mount */ void Plane::update_mount(void) { #if MOUNT == ENABLED camera_mount.update(); #endif #if CAMERA == ENABLED camera.trigger_pic_cleanup(); #endif } /* read and update compass */ void Plane::update_compass(void) { if (g.compass_enabled && compass.read()) { ahrs.set_compass(&compass); compass.learn_offsets(); if (should_log(MASK_LOG_COMPASS)) { DataFlash.Log_Write_Compass(compass); } } else { ahrs.set_compass(NULL); } } /* if the compass is enabled then try to accumulate a reading */ void Plane::compass_accumulate(void) { if (g.compass_enabled) { compass.accumulate(); } } /* try to accumulate a baro reading */ void Plane::barometer_accumulate(void) { barometer.accumulate(); } /* do 10Hz logging */ void Plane::update_logging1(void) { if (should_log(MASK_LOG_ATTITUDE_MED) && !should_log(MASK_LOG_ATTITUDE_FAST)) { Log_Write_Attitude(); } if (should_log(MASK_LOG_ATTITUDE_MED) && !should_log(MASK_LOG_IMU)) Log_Write_IMU(); } /* do 10Hz logging - part2 */ void Plane::update_logging2(void) { if (should_log(MASK_LOG_CTUN)) Log_Write_Control_Tuning(); if (should_log(MASK_LOG_NTUN)) Log_Write_Nav_Tuning(); if (should_log(MASK_LOG_RC)) Log_Write_RC(); #if HAL_CPU_CLASS >= HAL_CPU_CLASS_75 if (should_log(MASK_LOG_IMU)) DataFlash.Log_Write_Vibration(ins); #endif } /* check for OBC failsafe check */ void Plane::obc_fs_check(void) { #if OBC_FAILSAFE == ENABLED // perform OBC failsafe checks obc.check(OBC_MODE(control_mode), failsafe.last_heartbeat_ms, geofence_breached(), failsafe.last_valid_rc_ms); #endif } /* update aux servo mappings */ void Plane::update_aux(void) { RC_Channel_aux::enable_aux_servos(); } void Plane::one_second_loop() { if (should_log(MASK_LOG_CURRENT)) Log_Write_Current(); // send a heartbeat gcs_send_message(MSG_HEARTBEAT); // make it possible to change control channel ordering at runtime set_control_channels(); // make it possible to change orientation at runtime ahrs.set_orientation(); // sync MAVLink system ID mavlink_system.sysid = g.sysid_this_mav; update_aux(); // determine if we are flying or not determine_is_flying(); // 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::NO; #if AP_TERRAIN_AVAILABLE if (should_log(MASK_LOG_GPS)) { terrain.log_terrain_data(DataFlash); } #endif // piggyback the status log entry on the MODE log entry flag if (should_log(MASK_LOG_MODE)) { Log_Write_Status(); } #if HAL_CPU_CLASS >= HAL_CPU_CLASS_75 ins.set_raw_logging(should_log(MASK_LOG_IMU_RAW)); #endif } void Plane::log_perf_info() { if (scheduler.debug() != 0) { gcs_send_text_fmt(PSTR("G_Dt_max=%lu G_Dt_min=%lu\n"), (unsigned long)G_Dt_max, (unsigned long)G_Dt_min); } #if HAL_CPU_CLASS >= HAL_CPU_CLASS_75 if (should_log(MASK_LOG_PM)) Log_Write_Performance(); #endif G_Dt_max = 0; G_Dt_min = 0; resetPerfData(); } void Plane::compass_save() { if (g.compass_enabled) { compass.save_offsets(); } } void Plane::terrain_update(void) { #if AP_TERRAIN_AVAILABLE terrain.update(); // tell the rangefinder our height, so it can go into power saving // mode if available float height; if (terrain.height_above_terrain(height, true)) { rangefinder.set_estimated_terrain_height(height); } #endif } /* 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 (abs(ahrs.roll_sensor) > roll_limit_cd || ahrs.pitch_sensor > aparm.pitch_limit_max_cd || ahrs.pitch_sensor < pitch_limit_min_cd) { // don't calibrate when going beyond normal flight envelope return; } const Vector3f &vg = gps.velocity(); airspeed.update_calibration(vg); gcs_send_airspeed_calibration(vg); } /* read the GPS and update position */ void Plane::update_GPS_50Hz(void) { static uint32_t last_gps_reading[GPS_MAX_INSTANCES]; gps.update(); for (uint8_t i=0; i= 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) { ground_start_count = 5; } else { init_home(); // set system clock for log timestamps hal.util->set_system_clock(gps.time_epoch_usec()); if (g.compass_enabled) { // Set compass declination automatically const Location &loc = gps.location(); compass.set_initial_location(loc.lat, loc.lng); } ground_start_count = 0; } } // see if we've breached the geo-fence geofence_check(false); #if CAMERA == ENABLED if (camera.update_location(current_loc) == true) { do_take_picture(); } #endif if (!hal.util->get_soft_armed()) { update_home(); } // update wind estimate ahrs.estimate_wind(); } calc_gndspeed_undershoot(); } /* main handling for AUTO mode */ void Plane::handle_auto_mode(void) { uint8_t nav_cmd_id; // we should be either running a mission or RTLing home if (mission.state() == AP_Mission::MISSION_RUNNING) { nav_cmd_id = mission.get_current_nav_cmd().id; }else{ nav_cmd_id = auto_rtl_command.id; } switch(nav_cmd_id) { case MAV_CMD_NAV_TAKEOFF: takeoff_calc_roll(); takeoff_calc_pitch(); calc_throttle(); break; case MAV_CMD_NAV_LAND: calc_nav_roll(); calc_nav_pitch(); if (auto_state.land_complete) { // during final approach constrain roll to the range // allowed for level flight nav_roll_cd = constrain_int32(nav_roll_cd, -g.level_roll_limit*100UL, g.level_roll_limit*100UL); } calc_throttle(); if (auto_state.land_complete) { // we are in the final stage of a landing - force // zero throttle channel_throttle->servo_out = 0; } break; default: // we are doing normal AUTO flight, the special cases // are for takeoff and landing steer_state.hold_course_cd = -1; auto_state.land_complete = false; calc_nav_roll(); calc_nav_pitch(); calc_throttle(); break; } } /* main flight mode dependent update code */ void Plane::update_flight_mode(void) { enum FlightMode effective_mode = control_mode; if (control_mode == AUTO && g.auto_fbw_steer) { effective_mode = FLY_BY_WIRE_A; } if (effective_mode != AUTO) { // hold_course is only used in takeoff and landing steer_state.hold_course_cd = -1; } switch (effective_mode) { case AUTO: handle_auto_mode(); break; case RTL: case LOITER: case GUIDED: calc_nav_roll(); calc_nav_pitch(); calc_throttle(); break; case TRAINING: { training_manual_roll = false; training_manual_pitch = false; update_load_factor(); // if the roll is past the set roll limit, then // we set target roll to the limit if (ahrs.roll_sensor >= roll_limit_cd) { nav_roll_cd = roll_limit_cd; } else if (ahrs.roll_sensor <= -roll_limit_cd) { nav_roll_cd = -roll_limit_cd; } else { training_manual_roll = true; nav_roll_cd = 0; } // if the pitch is past the set pitch limits, then // we set target pitch to the limit if (ahrs.pitch_sensor >= aparm.pitch_limit_max_cd) { nav_pitch_cd = aparm.pitch_limit_max_cd; } else if (ahrs.pitch_sensor <= pitch_limit_min_cd) { nav_pitch_cd = pitch_limit_min_cd; } else { training_manual_pitch = true; nav_pitch_cd = 0; } if (fly_inverted()) { nav_pitch_cd = -nav_pitch_cd; } break; } case ACRO: { // handle locked/unlocked control if (acro_state.locked_roll) { nav_roll_cd = acro_state.locked_roll_err; } else { nav_roll_cd = ahrs.roll_sensor; } if (acro_state.locked_pitch) { nav_pitch_cd = acro_state.locked_pitch_cd; } else { nav_pitch_cd = ahrs.pitch_sensor; } break; } case AUTOTUNE: case FLY_BY_WIRE_A: { // set nav_roll and nav_pitch using sticks nav_roll_cd = channel_roll->norm_input() * roll_limit_cd; nav_roll_cd = constrain_int32(nav_roll_cd, -roll_limit_cd, roll_limit_cd); update_load_factor(); float pitch_input = channel_pitch->norm_input(); if (pitch_input > 0) { nav_pitch_cd = pitch_input * aparm.pitch_limit_max_cd; } else { nav_pitch_cd = -(pitch_input * pitch_limit_min_cd); } adjust_nav_pitch_throttle(); nav_pitch_cd = constrain_int32(nav_pitch_cd, pitch_limit_min_cd, aparm.pitch_limit_max_cd.get()); if (fly_inverted()) { nav_pitch_cd = -nav_pitch_cd; } if (failsafe.ch3_failsafe && g.short_fs_action == 2) { // FBWA failsafe glide nav_roll_cd = 0; nav_pitch_cd = 0; channel_throttle->servo_out = 0; } if (g.fbwa_tdrag_chan > 0) { // check for the user enabling FBWA taildrag takeoff mode bool tdrag_mode = (hal.rcin->read(g.fbwa_tdrag_chan-1) > 1700); if (tdrag_mode && !auto_state.fbwa_tdrag_takeoff_mode) { if (auto_state.highest_airspeed < g.takeoff_tdrag_speed1) { auto_state.fbwa_tdrag_takeoff_mode = true; gcs_send_text_P(SEVERITY_LOW, PSTR("FBWA tdrag mode\n")); } } } break; } case FLY_BY_WIRE_B: // Thanks to Yury MonZon for the altitude limit code! nav_roll_cd = channel_roll->norm_input() * roll_limit_cd; nav_roll_cd = constrain_int32(nav_roll_cd, -roll_limit_cd, roll_limit_cd); update_load_factor(); update_fbwb_speed_height(); break; case CRUISE: /* in CRUISE mode we use the navigation code to control roll when heading is locked. Heading becomes unlocked on any aileron or rudder input */ if ((channel_roll->control_in != 0 || rudder_input != 0)) { cruise_state.locked_heading = false; cruise_state.lock_timer_ms = 0; } if (!cruise_state.locked_heading) { nav_roll_cd = channel_roll->norm_input() * roll_limit_cd; nav_roll_cd = constrain_int32(nav_roll_cd, -roll_limit_cd, roll_limit_cd); update_load_factor(); } else { calc_nav_roll(); } update_fbwb_speed_height(); break; case STABILIZE: nav_roll_cd = 0; nav_pitch_cd = 0; // throttle is passthrough break; case CIRCLE: // we have no GPS installed and have lost radio contact // or we just want to fly around in a gentle circle w/o GPS, // holding altitude at the altitude we set when we // switched into the mode nav_roll_cd = roll_limit_cd / 3; update_load_factor(); calc_nav_pitch(); calc_throttle(); break; case MANUAL: // servo_out is for Sim control only // --------------------------------- channel_roll->servo_out = channel_roll->pwm_to_angle(); channel_pitch->servo_out = channel_pitch->pwm_to_angle(); steering_control.steering = steering_control.rudder = channel_rudder->pwm_to_angle(); break; //roll: -13788.000, pitch: -13698.000, thr: 0.000, rud: -13742.000 case INITIALISING: // handled elsewhere break; } } void Plane::update_navigation() { // wp_distance is in ACTUAL meters, not the *100 meters we get from the GPS // ------------------------------------------------------------------------ // distance and bearing calcs only switch(control_mode) { case AUTO: update_commands(); break; case RTL: if (g.rtl_autoland == 1 && !auto_state.checked_for_autoland && nav_controller->reached_loiter_target() && labs(altitude_error_cm) < 1000) { // we've reached the RTL point, see if we have a landing sequence jump_to_landing_sequence(); // prevent running the expensive jump_to_landing_sequence // on every loop auto_state.checked_for_autoland = true; } else if (g.rtl_autoland == 2 && !auto_state.checked_for_autoland) { // Go directly to the landing sequence jump_to_landing_sequence(); // prevent running the expensive jump_to_landing_sequence // on every loop auto_state.checked_for_autoland = true; } // fall through to LOITER case LOITER: case GUIDED: // allow loiter direction to be changed in flight if (g.loiter_radius < 0) { loiter.direction = -1; } else { loiter.direction = 1; } update_loiter(); break; case CRUISE: update_cruise(); break; case MANUAL: case STABILIZE: case TRAINING: case INITIALISING: case ACRO: case FLY_BY_WIRE_A: case AUTOTUNE: case FLY_BY_WIRE_B: case CIRCLE: // nothing to do break; } } /* set the flight stage */ void Plane::set_flight_stage(AP_SpdHgtControl::FlightStage fs) { //if just now entering land flight stage if (fs == AP_SpdHgtControl::FLIGHT_LAND_APPROACH && flight_stage != AP_SpdHgtControl::FLIGHT_LAND_APPROACH) { #if GEOFENCE_ENABLED == ENABLED if (g.fence_autoenable == 1) { if (! geofence_set_enabled(false, AUTO_TOGGLED)) { gcs_send_text_P(SEVERITY_HIGH, PSTR("Disable fence failed (autodisable)")); } else { gcs_send_text_P(SEVERITY_HIGH, PSTR("Fence disabled (autodisable)")); } } else if (g.fence_autoenable == 2) { if (! geofence_set_floor_enabled(false)) { gcs_send_text_P(SEVERITY_HIGH, PSTR("Disable fence floor failed (autodisable)")); } else { gcs_send_text_P(SEVERITY_HIGH, PSTR("Fence floor disabled (auto disable)")); } } #endif } flight_stage = fs; } void Plane::update_alt() { barometer.update(); if (should_log(MASK_LOG_IMU)) { Log_Write_Baro(); } // 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; geofence_check(true); update_flight_stage(); } /* recalculate the flight_stage */ void Plane::update_flight_stage(void) { // Update the speed & height controller states if (auto_throttle_mode && !throttle_suppressed) { if (control_mode==AUTO) { if (auto_state.takeoff_complete == false) { set_flight_stage(AP_SpdHgtControl::FLIGHT_TAKEOFF); } else if (mission.get_current_nav_cmd().id == MAV_CMD_NAV_LAND && auto_state.land_complete == true) { set_flight_stage(AP_SpdHgtControl::FLIGHT_LAND_FINAL); } else if (mission.get_current_nav_cmd().id == MAV_CMD_NAV_LAND) { set_flight_stage(AP_SpdHgtControl::FLIGHT_LAND_APPROACH); } else { set_flight_stage(AP_SpdHgtControl::FLIGHT_NORMAL); } } else { set_flight_stage(AP_SpdHgtControl::FLIGHT_NORMAL); } SpdHgt_Controller->update_pitch_throttle(relative_target_altitude_cm(), target_airspeed_cm, flight_stage, auto_state.takeoff_pitch_cd, throttle_nudge, tecs_hgt_afe(), aerodynamic_load_factor); if (should_log(MASK_LOG_TECS)) { Log_Write_TECS_Tuning(); } } // tell AHRS the airspeed to true airspeed ratio airspeed.set_EAS2TAS(barometer.get_EAS2TAS()); } /* Do we think we are flying? Probabilistic method where a bool is low-passed and considered a probability. */ void Plane::determine_is_flying(void) { float aspeed; bool isFlyingBool; bool airspeedMovement = ahrs.airspeed_estimate(&aspeed) && (aspeed >= 5); // If we don't have a GPS lock then don't use GPS for this test bool gpsMovement = (gps.status() < AP_GPS::GPS_OK_FIX_2D || gps.ground_speed() >= 5); if (hal.util->get_soft_armed()) { // when armed, we need overwhelming evidence that we ARE NOT flying isFlyingBool = airspeedMovement || gpsMovement; /* make is_flying() more accurate for landing approach */ if (flight_stage == AP_SpdHgtControl::FLIGHT_LAND_APPROACH && fabsf(auto_state.sink_rate) > 0.2f) { isFlyingBool = true; } } else { // when disarmed, we need overwhelming evidence that we ARE flying isFlyingBool = airspeedMovement && gpsMovement; } // low-pass the result. isFlyingProbability = (0.6f * isFlyingProbability) + (0.4f * (float)isFlyingBool); /* update last_flying_ms so we always know how long we have not been flying for. This helps for crash detection and auto-disarm */ if (is_flying()) { auto_state.last_flying_ms = millis(); } } /* return true if we think we are flying. This is a probabilistic estimate, and needs to be used very carefully. Each use case needs to be thought about individually. */ bool Plane::is_flying(void) { if (hal.util->get_soft_armed()) { // when armed, assume we're flying unless we probably aren't return (isFlyingProbability >= 0.1f); } // when disarmed, assume we're not flying unless we probably are return (isFlyingProbability >= 0.9f); } #if OPTFLOW == ENABLED // called at 50hz void Plane::update_optical_flow(void) { static uint32_t last_of_update = 0; // exit immediately if not enabled if (!optflow.enabled()) { return; } // read from sensor optflow.update(); // write to log and send to EKF if new data has arrived if (optflow.last_update() != last_of_update) { last_of_update = optflow.last_update(); uint8_t flowQuality = optflow.quality(); Vector2f flowRate = optflow.flowRate(); Vector2f bodyRate = optflow.bodyRate(); ahrs.writeOptFlowMeas(flowQuality, flowRate, bodyRate, last_of_update); Log_Write_Optflow(); } } #endif /* compatibility with old pde style build */ void setup(void); void loop(void); void setup(void) { plane.setup(); } void loop(void) { plane.loop(); } AP_HAL_MAIN();