/* 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 . */ #pragma once #include #include #include #include #include #include #include "AP_Landing_Deepstall.h" /// @class AP_Landing /// @brief Class managing ArduPlane landing methods class AP_Landing { friend class AP_Landing_Deepstall; public: FUNCTOR_TYPEDEF(set_target_altitude_proportion_fn_t, void, const Location&, float); FUNCTOR_TYPEDEF(constrain_target_altitude_location_fn_t, void, const Location&, const Location&); FUNCTOR_TYPEDEF(adjusted_altitude_cm_fn_t, int32_t); FUNCTOR_TYPEDEF(adjusted_relative_altitude_cm_fn_t, int32_t); FUNCTOR_TYPEDEF(disarm_if_autoland_complete_fn_t, void); FUNCTOR_TYPEDEF(update_flight_stage_fn_t, void); AP_Landing(AP_Mission &_mission, AP_AHRS &_ahrs, AP_SpdHgtControl *_SpdHgt_Controller, AP_Navigation *_nav_controller, AP_Vehicle::FixedWing &_aparm, set_target_altitude_proportion_fn_t _set_target_altitude_proportion_fn, constrain_target_altitude_location_fn_t _constrain_target_altitude_location_fn, adjusted_altitude_cm_fn_t _adjusted_altitude_cm_fn, adjusted_relative_altitude_cm_fn_t _adjusted_relative_altitude_cm_fn, disarm_if_autoland_complete_fn_t _disarm_if_autoland_complete_fn, update_flight_stage_fn_t _update_flight_stage_fn); /* Do not allow copies */ AP_Landing(const AP_Landing &other) = delete; AP_Landing &operator=(const AP_Landing&) = delete; // NOTE: make sure to update is_type_valid() enum Landing_Type { TYPE_STANDARD_GLIDE_SLOPE = 0, TYPE_DEEPSTALL = 1, // TODO: TYPE_PARACHUTE, // TODO: TYPE_HELICAL, }; void do_land(const AP_Mission::Mission_Command& cmd, const float relative_altitude); bool verify_abort_landing(const Location &prev_WP_loc, Location &next_WP_loc, const Location ¤t_loc, const int32_t auto_state_takeoff_altitude_rel_cm, bool &throttle_suppressed); bool verify_land(const Location &prev_WP_loc, Location &next_WP_loc, const Location ¤t_loc, const float height, const float sink_rate, const float wp_proportion, const uint32_t last_flying_ms, const bool is_armed, const bool is_flying, const bool rangefinder_state_in_range); void adjust_landing_slope_for_rangefinder_bump(AP_Vehicle::FixedWing::Rangefinder_State &rangefinder_state, Location &prev_WP_loc, Location &next_WP_loc, const Location ¤t_loc, const float wp_distance, int32_t &target_altitude_offset_cm); void setup_landing_glide_slope(const Location &prev_WP_loc, const Location &next_WP_loc, const Location ¤t_loc, int32_t &target_altitude_offset_cm); bool override_servos(void); void check_if_need_to_abort(const AP_Vehicle::FixedWing::Rangefinder_State &rangefinder_state); bool request_go_around(void); bool is_flaring(void) const; bool is_on_approach(void) const; bool is_ground_steering_allowed(void) const; bool is_throttle_suppressed(void) const; bool is_flying_forward(void) const; void handle_flight_stage_change(const bool _in_landing_stage); int32_t constrain_roll(const int32_t desired_roll_cd, const int32_t level_roll_limit_cd); bool get_target_altitude_location(Location &location); bool send_landing_message(mavlink_channel_t chan); // terminate the flight with an immediate landing, returns false if unable to be used for termination bool terminate(void); // helper functions bool restart_landing_sequence(void); float wind_alignment(const float heading_deg); float head_wind(void); int32_t get_target_airspeed_cm(void); // accessor functions for the params and states static const struct AP_Param::GroupInfo var_info[]; int16_t get_pitch_cd(void) const { return pitch_cd; } float get_flare_sec(void) const { return flare_sec; } int8_t get_disarm_delay(void) const { return disarm_delay; } int8_t get_then_servos_neutral(void) const { return then_servos_neutral; } int8_t get_abort_throttle_enable(void) const { return abort_throttle_enable; } int8_t get_flap_percent(void) const { return flap_percent; } int8_t get_throttle_slewrate(void) const { return throttle_slewrate; } bool is_commanded_go_around(void) const { return flags.commanded_go_around; } bool is_complete(void) const; void set_initial_slope(void) { initial_slope = slope; } bool is_expecting_impact(void) const; void log(void) const; const DataFlash_Class::PID_Info * get_pid_info(void) const; // landing altitude offset (meters) float alt_offset; private: struct { // denotes if a go-around has been commanded for landing bool commanded_go_around:1; // are we in auto and flight_stage is LAND bool in_progress:1; } flags; // same as land_slope but sampled once before a rangefinder changes the slope. This should be the original mission planned slope float initial_slope; // calculated approach slope during auto-landing: ((prev_WP_loc.alt - next_WP_loc.alt)*0.01f - flare_sec * sink_rate) / get_distance(prev_WP_loc, next_WP_loc) float slope; AP_Mission &mission; AP_AHRS &ahrs; AP_SpdHgtControl *SpdHgt_Controller; AP_Navigation *nav_controller; AP_Vehicle::FixedWing &aparm; set_target_altitude_proportion_fn_t set_target_altitude_proportion_fn; constrain_target_altitude_location_fn_t constrain_target_altitude_location_fn; adjusted_altitude_cm_fn_t adjusted_altitude_cm_fn; adjusted_relative_altitude_cm_fn_t adjusted_relative_altitude_cm_fn; disarm_if_autoland_complete_fn_t disarm_if_autoland_complete_fn; update_flight_stage_fn_t update_flight_stage_fn; // support for deepstall landings AP_Landing_Deepstall deepstall; AP_Int16 pitch_cd; AP_Float flare_alt; AP_Float flare_sec; AP_Float pre_flare_airspeed; AP_Float pre_flare_alt; AP_Float pre_flare_sec; AP_Float slope_recalc_shallow_threshold; AP_Float slope_recalc_steep_threshold_to_abort; AP_Int8 disarm_delay; AP_Int8 then_servos_neutral; AP_Int8 abort_throttle_enable; AP_Int8 flap_percent; AP_Int8 throttle_slewrate; AP_Int8 type; // Land Type STANDARD GLIDE SLOPE enum { SLOPE_STAGE_NORMAL, SLOPE_STAGE_APPROACH, SLOPE_STAGE_PREFLARE, SLOPE_STAGE_FINAL } type_slope_stage; struct { // once landed, post some landing statistics to the GCS bool post_stats:1; bool has_aborted_due_to_slope_recalc:1; } type_slope_flags; void type_slope_do_land(const AP_Mission::Mission_Command& cmd, const float relative_altitude); void type_slope_verify_abort_landing(const Location &prev_WP_loc, Location &next_WP_loc, bool &throttle_suppressed); bool type_slope_verify_land(const Location &prev_WP_loc, Location &next_WP_loc, const Location ¤t_loc, const float height, const float sink_rate, const float wp_proportion, const uint32_t last_flying_ms, const bool is_armed, const bool is_flying, const bool rangefinder_state_in_range); void type_slope_adjust_landing_slope_for_rangefinder_bump(AP_Vehicle::FixedWing::Rangefinder_State &rangefinder_state, Location &prev_WP_loc, Location &next_WP_loc, const Location ¤t_loc, const float wp_distance, int32_t &target_altitude_offset_cm); void type_slope_setup_landing_glide_slope(const Location &prev_WP_loc, const Location &next_WP_loc, const Location ¤t_loc, int32_t &target_altitude_offset_cm); int32_t type_slope_get_target_airspeed_cm(void); void type_slope_check_if_need_to_abort(const AP_Vehicle::FixedWing::Rangefinder_State &rangefinder_state); int32_t type_slope_constrain_roll(const int32_t desired_roll_cd, const int32_t level_roll_limit_cd); bool type_slope_request_go_around(void); void type_slope_log(void) const; bool type_slope_is_complete(void) const; bool type_slope_is_flaring(void) const; bool type_slope_is_on_approach(void) const; bool type_slope_is_expecting_impact(void) const; bool type_slope_is_throttle_suppressed(void) const; };