#include "Copter.h" #include // statistics library // Code to detect a crash main ArduCopter code #define LAND_CHECK_ANGLE_ERROR_DEG 30.0f // maximum angle error to be considered landing #define LAND_CHECK_LARGE_ANGLE_CD 1500.0f // maximum angle target to be considered landing #define LAND_CHECK_ACCEL_MOVING 3.0f // maximum acceleration after subtracting gravity // counter to verify landings static uint32_t land_detector_count = 0; // run land and crash detectors // called at MAIN_LOOP_RATE void Copter::update_land_and_crash_detectors() { // update 1hz filtered acceleration Vector3f accel_ef = ahrs.get_accel_ef(); accel_ef.z += GRAVITY_MSS; land_accel_ef_filter.apply(accel_ef, scheduler.get_loop_period_s()); update_land_detector(); #if PARACHUTE == ENABLED // check parachute parachute_check(); #endif crash_check(); thrust_loss_check(); yaw_imbalance_check(); } // update_land_detector - checks if we have landed and updates the ap.land_complete flag // called at MAIN_LOOP_RATE void Copter::update_land_detector() { // land detector can not use the following sensors because they are unreliable during landing // barometer altitude : ground effect can cause errors larger than 4m // EKF vertical velocity or altitude : poor barometer and large acceleration from ground impact // earth frame angle or angle error : landing on an uneven surface will force the airframe to match the ground angle // gyro output : on uneven surface the airframe may rock back an forth after landing // range finder : tend to be problematic at very short distances // input throttle : in slow land the input throttle may be only slightly less than hover if (!motors->armed()) { // if disarmed, always landed. set_land_complete(true); } else if (ap.land_complete) { #if FRAME_CONFIG == HELI_FRAME // if rotor speed and collective pitch are high then clear landing flag if (!flightmode->is_taking_off() && motors->get_takeoff_collective() && motors->get_spool_state() == AP_Motors::SpoolState::THROTTLE_UNLIMITED) { #else // if throttle output is high then clear landing flag if (!flightmode->is_taking_off() && motors->get_throttle_out() > get_non_takeoff_throttle() && motors->get_spool_state() == AP_Motors::SpoolState::THROTTLE_UNLIMITED) { // this should never happen because take-off should be detected at the flight mode level // this here to highlight there is a bug or missing take-off detection INTERNAL_ERROR(AP_InternalError::error_t::flow_of_control); #endif set_land_complete(false); } } else if (standby_active) { // land detector will not run in standby mode land_detector_count = 0; } else { float land_trigger_sec = LAND_DETECTOR_TRIGGER_SEC; #if FRAME_CONFIG == HELI_FRAME // check for both manual collective modes and modes that use altitude hold. For manual collective (called throttle // because multi's use throttle), check that collective pitch is below land min collective position or throttle stick is zero. // Including the throttle zero check will ensure the conditions where stabilize stick zero position was not below collective min. For modes // that use altitude hold, check that the pilot is commanding a descent and collective is at min allowed for altitude hold modes. // check if landing const bool landing = flightmode->is_landing(); bool motor_at_lower_limit = (flightmode->has_manual_throttle() && (motors->get_below_land_min_coll() || heli_flags.coll_stk_low) && fabsf(ahrs.get_roll()) < M_PI/2.0f) #if MODE_AUTOROTATE_ENABLED == ENABLED || (flightmode->mode_number() == Mode::Number::AUTOROTATE && motors->get_below_land_min_coll()) #endif || ((!force_flying || landing) && motors->limit.throttle_lower && pos_control->get_vel_desired_cms().z < 0.0f); bool throttle_mix_at_min = true; #else // check that the average throttle output is near minimum (less than 12.5% hover throttle) bool motor_at_lower_limit = motors->limit.throttle_lower; bool throttle_mix_at_min = attitude_control->is_throttle_mix_min(); // set throttle_mix_at_min to true because throttle is never at mix min in airmode // increase land_trigger_sec when using airmode if (flightmode->has_manual_throttle() && air_mode == AirMode::AIRMODE_ENABLED) { land_trigger_sec = LAND_AIRMODE_DETECTOR_TRIGGER_SEC; throttle_mix_at_min = true; } #endif uint8_t land_detector_scalar = 1; #if AP_LANDINGGEAR_ENABLED if (landinggear.get_wow_state() != AP_LandingGear::LG_WOW_UNKNOWN) { // we have a WoW sensor so lets loosen the strictness of the landing detector land_detector_scalar = 2; } #endif // check that the airframe is not accelerating (not falling or braking after fast forward flight) bool accel_stationary = (land_accel_ef_filter.get().length() <= LAND_DETECTOR_ACCEL_MAX * land_detector_scalar); // check that vertical speed is within 1m/s of zero bool descent_rate_low = fabsf(inertial_nav.get_velocity_z_up_cms()) < 100 * land_detector_scalar; // if we have a healthy rangefinder only allow landing detection below 2 meters bool rangefinder_check = (!rangefinder_alt_ok() || rangefinder_state.alt_cm_filt.get() < LAND_RANGEFINDER_MIN_ALT_CM); // if we have weight on wheels (WoW) or ambiguous unknown. never no WoW #if AP_LANDINGGEAR_ENABLED const bool WoW_check = (landinggear.get_wow_state() == AP_LandingGear::LG_WOW || landinggear.get_wow_state() == AP_LandingGear::LG_WOW_UNKNOWN); #else const bool WoW_check = true; #endif if (motor_at_lower_limit && throttle_mix_at_min && accel_stationary && descent_rate_low && rangefinder_check && WoW_check) { // landed criteria met - increment the counter and check if we've triggered if( land_detector_count < land_trigger_sec*scheduler.get_loop_rate_hz()) { land_detector_count++; } else { set_land_complete(true); } } else { // we've sensed movement up or down so reset land_detector land_detector_count = 0; } } set_land_complete_maybe(ap.land_complete || (land_detector_count >= LAND_DETECTOR_MAYBE_TRIGGER_SEC*scheduler.get_loop_rate_hz())); } // set land_complete flag and disarm motors if disarm-on-land is configured void Copter::set_land_complete(bool b) { // if no change, exit immediately if( ap.land_complete == b ) return; land_detector_count = 0; #if HAL_LOGGING_ENABLED if(b){ AP::logger().Write_Event(LogEvent::LAND_COMPLETE); } else { AP::logger().Write_Event(LogEvent::NOT_LANDED); } #endif ap.land_complete = b; #if AP_STATS_ENABLED AP::stats()->set_flying(!b); #endif // tell AHRS flying state set_likely_flying(!b); if (!b) { // not landed, no further action return; } // landed; trigger disarm-on-land if configured if ((g.throttle_behavior & THR_BEHAVE_DISARM_ON_LAND_DETECT) == 0) { // not configured to disarm on landing detection return; } if (!motors->armed()) { // we are not currently armed, so we don't need to disarm: // n.b. should this be checking vehicle-armed rather than motors-armed? return; } if (flightmode->has_manual_throttle()) { // we do not use the landing detector to disarm if the vehicle // is in e.g. STABILIZE. The normal DISARM_DELAY logic applies. return; } // the flightmode may not allow disarm on landing. Note that this // check returns false for the LAND flight mode - it checks the // landing detector (ap.land_complete) itself. if (!flightmode->allows_arming(AP_Arming::Method::LANDING)) { return; } // all checks passed, disarm the vehicle: arming.disarm(AP_Arming::Method::LANDED); } // set land complete maybe flag void Copter::set_land_complete_maybe(bool b) { // if no change, exit immediately if (ap.land_complete_maybe == b) return; if (b) { LOGGER_WRITE_EVENT(LogEvent::LAND_COMPLETE_MAYBE); } ap.land_complete_maybe = b; } // sets motors throttle_low_comp value depending upon vehicle state // low values favour pilot/autopilot throttle over attitude control, high values favour attitude control over throttle // has no effect when throttle is above hover throttle void Copter::update_throttle_mix() { #if FRAME_CONFIG != HELI_FRAME // if disarmed or landed prioritise throttle if (!motors->armed() || ap.land_complete) { attitude_control->set_throttle_mix_min(); return; } if (flightmode->has_manual_throttle()) { // manual throttle if (channel_throttle->get_control_in() <= 0 && air_mode != AirMode::AIRMODE_ENABLED) { attitude_control->set_throttle_mix_min(); } else { attitude_control->set_throttle_mix_man(); } } else { // autopilot controlled throttle // check for aggressive flight requests - requested roll or pitch angle below 15 degrees const Vector3f angle_target = attitude_control->get_att_target_euler_cd(); bool large_angle_request = angle_target.xy().length() > LAND_CHECK_LARGE_ANGLE_CD; // check for large external disturbance - angle error over 30 degrees const float angle_error = attitude_control->get_att_error_angle_deg(); bool large_angle_error = (angle_error > LAND_CHECK_ANGLE_ERROR_DEG); // check for large acceleration - falling or high turbulence const bool accel_moving = (land_accel_ef_filter.get().length() > LAND_CHECK_ACCEL_MOVING); // check for requested descent bool descent_not_demanded = pos_control->get_vel_desired_cms().z >= 0.0f; // check if landing const bool landing = flightmode->is_landing(); if (((large_angle_request || force_flying) && !landing) || large_angle_error || accel_moving || descent_not_demanded) { attitude_control->set_throttle_mix_max(pos_control->get_vel_z_control_ratio()); } else { attitude_control->set_throttle_mix_min(); } } #endif }