#pragma once /* 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 . */ /* Situational awareness for ArduPilot - record a series of moving points in space which should be avoided - produce messages for GCS if a collision risk is detected Peter Barker, May 2016 based on AP_ADSB, Tom Pittenger, November 2015 */ #include // F_RCVRY possible parameter values #define AP_AVOIDANCE_RECOVERY_REMAIN_IN_AVOID_ADSB 0 #define AP_AVOIDANCE_RECOVERY_RESUME_PREVIOUS_FLIGHTMODE 1 #define AP_AVOIDANCE_RECOVERY_RTL 2 #define AP_AVOIDANCE_RECOVERY_RESUME_IF_AUTO_ELSE_LOITER 3 #define AP_AVOIDANCE_STATE_RECOVERY_TIME_MS 2000 // we will not downgrade state any faster than this (2 seconds) #define AP_AVOIDANCE_ESCAPE_TIME_SEC 2 // vehicle runs from thread for 2 seconds class AP_Avoidance { public: // constructor AP_Avoidance(class AP_ADSB &adsb); /* Do not allow copies */ AP_Avoidance(const AP_Avoidance &other) = delete; AP_Avoidance &operator=(const AP_Avoidance&) = delete; // get singleton instance static AP_Avoidance *get_singleton() { return _singleton; } // obstacle class to hold latest information for a known obstacles class Obstacle { public: MAV_COLLISION_SRC src; uint32_t src_id; uint32_t timestamp_ms; Location _location; Vector3f _velocity; // fields relating to this being a threat. These would be the reason to have a separate list of threats: MAV_COLLISION_THREAT_LEVEL threat_level; float closest_approach_xy; // metres float closest_approach_z; // metres float time_to_closest_approach; // seconds, 3D approach float distance_to_closest_approach; // metres, 3D uint32_t last_gcs_report_time; // millis }; // add obstacle to the list of known obstacles void add_obstacle(uint32_t obstacle_timestamp_ms, const MAV_COLLISION_SRC src, uint32_t src_id, const Location &loc, const Vector3f &vel_ned); void add_obstacle(uint32_t obstacle_timestamp_ms, const MAV_COLLISION_SRC src, uint32_t src_id, const Location &loc, float cog, float hspeed, float vspeed); // update should be called at 10hz or higher void update(); // enable or disable avoidance void enable() { _enabled = true; }; void disable() { _enabled = false; }; // current overall threat level MAV_COLLISION_THREAT_LEVEL current_threat_level() const; // add obstacles into the Avoidance system from MAVLink messages void handle_msg(const mavlink_message_t &msg); // for holding parameters static const struct AP_Param::GroupInfo var_info[]; protected: // top level avoidance handler. This calls the vehicle specific handle_avoidance with requested action void handle_avoidance_local(AP_Avoidance::Obstacle *threat); // avoid the most significant threat. child classes must override this method // function returns the action that it is actually taking virtual MAV_COLLISION_ACTION handle_avoidance(const AP_Avoidance::Obstacle *obstacle, MAV_COLLISION_ACTION requested_action) = 0; // recover after all threats have cleared. child classes must override this method // recovery_action is from F_RCVRY parameter virtual void handle_recovery(uint8_t recovery_action) = 0; uint32_t _last_state_change_ms = 0; MAV_COLLISION_THREAT_LEVEL _threat_level = MAV_COLLISION_THREAT_LEVEL_NONE; // gcs notification // specifies how long we should continue sending messages about a threat after it has cleared static const uint8_t _gcs_cleared_messages_duration = 5; // seconds uint32_t _gcs_cleared_messages_first_sent; void handle_threat_gcs_notify(AP_Avoidance::Obstacle *threat); AP_Avoidance::Obstacle *most_serious_threat(); // returns an entry from the MAV_COLLISION_ACTION representative // of what the current avoidance handler is up to. MAV_COLLISION_ACTION mav_avoidance_action() { return _latest_action; } // get target destination that best gets vehicle away from the nearest obstacle bool get_destination_perpendicular(const AP_Avoidance::Obstacle *obstacle, Vector3f &newdest_neu, const float wp_speed_xy, const float wp_speed_z, const uint8_t _minimum_avoid_height); // get unit vector away from the nearest obstacle bool get_vector_perpendicular(const AP_Avoidance::Obstacle *obstacle, Vector3f &vec_neu); // helper functions to calculate destination to get us away from obstacle // Note: v1 is NED static Vector3f perpendicular_xyz(const Location &p1, const Vector3f &v1, const Location &p2); static Vector2f perpendicular_xy(const Location &p1, const Vector3f &v1, const Location &p2); private: void send_collision_all(const AP_Avoidance::Obstacle &threat, MAV_COLLISION_ACTION behaviour) const; // constants const uint32_t MAX_OBSTACLE_AGE_MS = 5000; // obstacles that have not been heard from for 5 seconds are removed from the list const static uint8_t _gcs_notify_interval = 1; // seconds // speed below which we will fly directly away from a threat // rather than perpendicular to its velocity: const uint8_t _low_velocity_threshold = 1; // meters/second // check to see if we are initialised (and possibly do initialisation) bool check_startup(); // initialize _obstacle_list void init(); // free _obstacle_list void deinit(); // get unique id for adsb uint32_t src_id_for_adsb_vehicle(const AP_ADSB::adsb_vehicle_t &vehicle) const; void check_for_threats(); void update_threat_level(const Location &my_loc, const Vector3f &my_vel, AP_Avoidance::Obstacle &obstacle); // calls into the AP_ADSB library to retrieve vehicle data void get_adsb_samples(); // returns true if the obstacle should be considered more of a // threat than the current most serious threat bool obstacle_is_more_serious_threat(const AP_Avoidance::Obstacle &obstacle) const; // internal variables AP_Avoidance::Obstacle *_obstacles; uint8_t _obstacles_allocated; uint8_t _obstacle_count; int8_t _current_most_serious_threat; MAV_COLLISION_ACTION _latest_action = MAV_COLLISION_ACTION_NONE; // external references class AP_ADSB &_adsb; // parameters AP_Int8 _enabled; AP_Int8 _obstacles_max; AP_Int8 _fail_action; AP_Int8 _fail_recovery; AP_Int8 _fail_time_horizon; AP_Int16 _fail_distance_xy; AP_Int16 _fail_distance_z; AP_Int16 _fail_altitude_minimum; AP_Int8 _warn_action; AP_Int8 _warn_time_horizon; AP_Float _warn_distance_xy; AP_Float _warn_distance_z; // multi-thread support for avoidance HAL_Semaphore _rsem; static AP_Avoidance *_singleton; }; float closest_approach_xy(const Location &my_loc, const Vector3f &my_vel, const Location &obstacle_loc, const Vector3f &obstacle_vel, uint8_t time_horizon); float closest_approach_z(const Location &my_loc, const Vector3f &my_vel, const Location &obstacle_loc, const Vector3f &obstacle_vel, uint8_t time_horizon); namespace AP { AP_Avoidance *ap_avoidance(); };