/* 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 /* This is the main Copter class */ //////////////////////////////////////////////////////////////////////////////// // Header includes //////////////////////////////////////////////////////////////////////////////// #include #include #include #include // Common dependencies #include #include #include #include // Application dependencies #include #include // Serial manager library #include // ArduPilot GPS library #include // ArduPilot Mega Flash Memory Library #include #include // ArduPilot Mega Magnetometer Library #include // ArduPilot Mega Vector/Matrix math Library #include // interface and maths for accelerometer calibration #include // ArduPilot Mega Inertial Sensor (accel & gyro) Library #include #include #include #include // Mission command library #include // P library #include // PID library #include // PI library (2-axis) #include // PID library (2-axis) #include // Heli specific Rate PID library #include // Attitude control library #include // Attitude control library for traditional helicopter #include // Position control library #include // RC Channel Library #include // AP Motors library #include // statistics library #include // RSSI Library #include // Filter library #include // APM FIFO Buffer #include // APM relay #include #include // needed for AHRS build #include // needed for AHRS build #include // ArduPilot Mega inertial navigation library #include // ArduCopter waypoint navigation library #include #include // circle navigation library #include // ArduPilot Mega Declination Helper Library #include // main loop scheduler #include // RC input mapping library #include // Notify library #include // Battery monitor library #include // board configuration library #include #include // Landing Gear library #include // Pilot input handling library #include // Heli specific pilot input handling library #include #include #include #include // Configuration #include "defines.h" #include "config.h" #include "GCS_Mavlink.h" #include "GCS_Copter.h" #include "AP_Rally.h" // Rally point library #include "AP_Arming.h" // libraries which are dependent on #defines in defines.h and/or config.h #if BEACON_ENABLED == ENABLED #include #endif #if AC_AVOID_ENABLED == ENABLED #include #endif #if SPRAYER_ENABLED == ENABLED # include #endif #if GRIPPER_ENABLED == ENABLED # include #endif #if PARACHUTE == ENABLED # include #endif #if PRECISION_LANDING == ENABLED # include # include #endif #if FRSKY_TELEM_ENABLED == ENABLED # include #endif #if ADSB_ENABLED == ENABLED # include #endif #if MODE_FOLLOW_ENABLED == ENABLED # include #endif #if AC_FENCE == ENABLED # include #endif #if AC_TERRAIN == ENABLED # include #endif #if OPTFLOW == ENABLED # include #endif #if VISUAL_ODOMETRY_ENABLED == ENABLED # include #endif #if RANGEFINDER_ENABLED == ENABLED # include #endif #if PROXIMITY_ENABLED == ENABLED # include #endif #if MOUNT == ENABLED #include #endif #if CAMERA == ENABLED # include #endif #if DEVO_TELEM_ENABLED == ENABLED #include #endif #if OSD_ENABLED == ENABLED #include #endif #if ADVANCED_FAILSAFE == ENABLED # include "afs_copter.h" #endif #if TOY_MODE_ENABLED == ENABLED # include "toy_mode.h" #endif #if WINCH_ENABLED == ENABLED # include # include #endif #if RPM_ENABLED == ENABLED #include #endif // Local modules #include "Parameters.h" #if ADSB_ENABLED == ENABLED #include "avoidance_adsb.h" #endif #if CONFIG_HAL_BOARD == HAL_BOARD_SITL #include #endif class Copter : public AP_HAL::HAL::Callbacks { public: friend class GCS_MAVLINK_Copter; friend class GCS_Copter; friend class AP_Rally_Copter; friend class Parameters; friend class ParametersG2; friend class AP_Avoidance_Copter; #if ADVANCED_FAILSAFE == ENABLED friend class AP_AdvancedFailsafe_Copter; #endif friend class AP_Arming_Copter; friend class ToyMode; Copter(void); // HAL::Callbacks implementation. void setup() override; void loop() override; private: static const AP_FWVersion fwver; // key aircraft parameters passed to multiple libraries AP_Vehicle::MultiCopter aparm; // Global parameters are all contained within the 'g' class. Parameters g; ParametersG2 g2; // main loop scheduler AP_Scheduler scheduler{FUNCTOR_BIND_MEMBER(&Copter::fast_loop, void)}; // AP_Notify instance AP_Notify notify; // used to detect MAVLink acks from GCS to stop compassmot uint8_t command_ack_counter; // primary input control channels RC_Channel *channel_roll; RC_Channel *channel_pitch; RC_Channel *channel_throttle; RC_Channel *channel_yaw; // Dataflash DataFlash_Class DataFlash; AP_GPS gps; // flight modes convenience array AP_Int8 *flight_modes; AP_Baro barometer; Compass compass; AP_InertialSensor ins; RangeFinder rangefinder{serial_manager, ROTATION_PITCH_270}; struct { bool enabled:1; bool alt_healthy:1; // true if we can trust the altitude from the rangefinder int16_t alt_cm; // tilt compensated altitude (in cm) from rangefinder uint32_t last_healthy_ms; LowPassFilterFloat alt_cm_filt; // altitude filter int8_t glitch_count; } rangefinder_state = { false, false, 0, 0 }; #if RPM_ENABLED == ENABLED AP_RPM rpm_sensor; #endif // Inertial Navigation EKF NavEKF2 EKF2{&ahrs, rangefinder}; NavEKF3 EKF3{&ahrs, rangefinder}; AP_AHRS_NavEKF ahrs{EKF2, EKF3, AP_AHRS_NavEKF::FLAG_ALWAYS_USE_EKF}; #if CONFIG_HAL_BOARD == HAL_BOARD_SITL SITL::SITL sitl; #endif // Mission library #if MODE_AUTO_ENABLED == ENABLED AP_Mission mission{ahrs, FUNCTOR_BIND_MEMBER(&Copter::start_command, bool, const AP_Mission::Mission_Command &), FUNCTOR_BIND_MEMBER(&Copter::verify_command_callback, bool, const AP_Mission::Mission_Command &), FUNCTOR_BIND_MEMBER(&Copter::exit_mission, void)}; bool start_command(const AP_Mission::Mission_Command& cmd) { return mode_auto.start_command(cmd); } bool verify_command_callback(const AP_Mission::Mission_Command& cmd) { return mode_auto.verify_command_callback(cmd); } void exit_mission() { mode_auto.exit_mission(); } #endif // Arming/Disarming mangement class AP_Arming_Copter arming{ahrs, compass, battery, inertial_nav}; // Optical flow sensor #if OPTFLOW == ENABLED OpticalFlow optflow{ahrs}; #endif // gnd speed limit required to observe optical flow sensor limits float ekfGndSpdLimit; // scale factor applied to velocity controller gain to prevent optical flow noise causing excessive angle demand noise float ekfNavVelGainScaler; // system time in milliseconds of last recorded yaw reset from ekf uint32_t ekfYawReset_ms; int8_t ekf_primary_core; AP_SerialManager serial_manager; // GCS selection GCS_Copter _gcs; // avoid using this; use gcs() GCS_Copter &gcs() { return _gcs; } // User variables #ifdef USERHOOK_VARIABLES # include USERHOOK_VARIABLES #endif // Documentation of GLobals: typedef union { struct { uint8_t unused1 : 1; // 0 uint8_t simple_mode : 2; // 1,2 // This is the state of simple mode : 0 = disabled ; 1 = SIMPLE ; 2 = SUPERSIMPLE uint8_t pre_arm_rc_check : 1; // 3 // true if rc input pre-arm checks have been completed successfully uint8_t pre_arm_check : 1; // 4 // true if all pre-arm checks (rc, accel calibration, gps lock) have been performed uint8_t auto_armed : 1; // 5 // stops auto missions from beginning until throttle is raised uint8_t logging_started : 1; // 6 // true if dataflash logging has started uint8_t land_complete : 1; // 7 // true if we have detected a landing uint8_t new_radio_frame : 1; // 8 // Set true if we have new PWM data to act on from the Radio uint8_t usb_connected_unused : 1; // 9 // UNUSED uint8_t rc_receiver_present : 1; // 10 // true if we have an rc receiver present (i.e. if we've ever received an update uint8_t compass_mot : 1; // 11 // true if we are currently performing compassmot calibration uint8_t motor_test : 1; // 12 // true if we are currently performing the motors test uint8_t initialised : 1; // 13 // true once the init_ardupilot function has completed. Extended status to GCS is not sent until this completes uint8_t land_complete_maybe : 1; // 14 // true if we may have landed (less strict version of land_complete) uint8_t throttle_zero : 1; // 15 // true if the throttle stick is at zero, debounced, determines if pilot intends shut-down when not using motor interlock uint8_t system_time_set_unused : 1; // 16 // true if the system time has been set from the GPS uint8_t gps_glitching : 1; // 17 // true if GPS glitching is affecting navigation accuracy uint8_t using_interlock : 1; // 20 // aux switch motor interlock function is in use uint8_t motor_emergency_stop : 1; // 21 // motor estop switch, shuts off motors when enabled uint8_t land_repo_active : 1; // 22 // true if the pilot is overriding the landing position uint8_t motor_interlock_switch : 1; // 23 // true if pilot is requesting motor interlock enable uint8_t in_arming_delay : 1; // 24 // true while we are armed but waiting to spin motors uint8_t initialised_params : 1; // 25 // true when the all parameters have been initialised. we cannot send parameters to the GCS until this is done uint8_t compass_init_location : 1; // 26 // true when the compass's initial location has been set uint8_t rc_override_enable : 1; // 27 // aux switch rc_override is allowed uint8_t armed_with_switch : 1; // 28 // we armed using a arming switch }; uint32_t value; } ap_t; ap_t ap; static_assert(sizeof(uint32_t) == sizeof(ap), "ap_t must be uint32_t"); // This is the state of the flight control system // There are multiple states defined such as STABILIZE, ACRO, control_mode_t control_mode; mode_reason_t control_mode_reason = MODE_REASON_UNKNOWN; control_mode_t prev_control_mode; mode_reason_t prev_control_mode_reason = MODE_REASON_UNKNOWN; // Structure used to detect changes in the flight mode control switch struct { int8_t debounced_switch_position; // currently used switch position int8_t last_switch_position; // switch position in previous iteration uint32_t last_edge_time_ms; // system time that switch position was last changed } control_switch_state; // de-bounce counters for switches.cpp struct debounce { uint8_t count; uint8_t ch_flag; } aux_debounce[(CH_12 - CH_7)+1]; // altitude below which we do no navigation in auto takeoff float auto_takeoff_no_nav_alt_cm; RCMapper rcmap; // intertial nav alt when we armed float arming_altitude_m; // board specific config AP_BoardConfig BoardConfig; #if HAL_WITH_UAVCAN // board specific config for CAN bus AP_BoardConfig_CAN BoardConfig_CAN; #endif // Failsafe struct { uint32_t last_heartbeat_ms; // the time when the last HEARTBEAT message arrived from a GCS - used for triggering gcs failsafe uint32_t terrain_first_failure_ms; // the first time terrain data access failed - used to calculate the duration of the failure uint32_t terrain_last_failure_ms; // the most recent time terrain data access failed int8_t radio_counter; // number of iterations with throttle below throttle_fs_value uint8_t rc_override_active : 1; // true if rc control are overwritten by ground station uint8_t radio : 1; // A status flag for the radio failsafe uint8_t gcs : 1; // A status flag for the ground station failsafe uint8_t ekf : 1; // true if ekf failsafe has occurred uint8_t terrain : 1; // true if the missing terrain data failsafe has occurred uint8_t adsb : 1; // true if an adsb related failsafe has occurred } failsafe; bool any_failsafe_triggered() const { return failsafe.radio || battery.has_failsafed() || failsafe.gcs || failsafe.ekf || failsafe.terrain || failsafe.adsb; } // sensor health for logging struct { uint8_t baro : 1; // true if baro is healthy uint8_t compass : 1; // true if compass is healthy uint8_t primary_gps : 2; // primary gps index } sensor_health; // Motor Output #if FRAME_CONFIG == HELI_FRAME #define MOTOR_CLASS AP_MotorsHeli #else #define MOTOR_CLASS AP_MotorsMulticopter #endif MOTOR_CLASS *motors; const struct AP_Param::GroupInfo *motors_var_info; // GPS variables // Sometimes we need to remove the scaling for distance calcs float scaleLongDown; int32_t _home_bearing; uint32_t _home_distance; // SIMPLE Mode // Used to track the orientation of the vehicle for Simple mode. This value is reset at each arming // or in SuperSimple mode when the vehicle leaves a 20m radius from home. float simple_cos_yaw; float simple_sin_yaw; int32_t super_simple_last_bearing; float super_simple_cos_yaw; float super_simple_sin_yaw; // Stores initial bearing when armed - initial simple bearing is modified in super simple mode so not suitable int32_t initial_armed_bearing; // Battery Sensors AP_BattMonitor battery{MASK_LOG_CURRENT, FUNCTOR_BIND_MEMBER(&Copter::handle_battery_failsafe, void, const char*, const int8_t), _failsafe_priorities}; #if FRSKY_TELEM_ENABLED == ENABLED // FrSky telemetry support AP_Frsky_Telem frsky_telemetry{ahrs, battery, rangefinder}; #endif #if DEVO_TELEM_ENABLED == ENABLED AP_DEVO_Telem devo_telemetry{ahrs}; #endif #if OSD_ENABLED == ENABLED AP_OSD osd; #endif // Variables for extended status MAVLink messages uint32_t control_sensors_present; uint32_t control_sensors_enabled; uint32_t control_sensors_health; // Altitude // The cm/s we are moving up or down based on filtered data - Positive = UP int16_t climb_rate; float target_rangefinder_alt; // desired altitude in cm above the ground bool target_rangefinder_alt_used; // true if mode is using target_rangefinder_alt int32_t baro_alt; // barometer altitude in cm above home float baro_climbrate; // barometer climbrate in cm/s LowPassFilterVector3f land_accel_ef_filter; // accelerations for land and crash detector tests // filtered pilot's throttle input used to cancel landing if throttle held high LowPassFilterFloat rc_throttle_control_in_filter; // 3D Location vectors // Current location of the vehicle (altitude is relative to home) Location_Class current_loc; // IMU variables // Integration time (in seconds) for the gyros (DCM algorithm) // Updated with the fast loop float G_Dt; // Inertial Navigation AP_InertialNav_NavEKF inertial_nav; // Attitude, Position and Waypoint navigation objects // To-Do: move inertial nav up or other navigation variables down here #if FRAME_CONFIG == HELI_FRAME #define AC_AttitudeControl_t AC_AttitudeControl_Heli #else #define AC_AttitudeControl_t AC_AttitudeControl_Multi #endif AC_AttitudeControl_t *attitude_control; AC_PosControl *pos_control; AC_WPNav *wp_nav; AC_Loiter *loiter_nav; #if MODE_CIRCLE_ENABLED == ENABLED AC_Circle *circle_nav; #endif // System Timers // -------------- // arm_time_ms - Records when vehicle was armed. Will be Zero if we are disarmed. uint32_t arm_time_ms; // Used to exit the roll and pitch auto trim function uint8_t auto_trim_counter; // Reference to the relay object AP_Relay relay; // handle repeated servo and relay events AP_ServoRelayEvents ServoRelayEvents{relay}; // Camera #if CAMERA == ENABLED AP_Camera camera{&relay, MASK_LOG_CAMERA, current_loc, ahrs}; #endif // Camera/Antenna mount tracking and stabilisation stuff #if MOUNT == ENABLED // current_loc uses the baro/gps solution for altitude rather than gps only. AP_Mount camera_mount{ahrs, current_loc}; #endif // AC_Fence library to reduce fly-aways #if AC_FENCE == ENABLED AC_Fence fence{ahrs}; #endif #if AC_AVOID_ENABLED == ENABLED # if BEACON_ENABLED == ENABLED AC_Avoid avoid{ahrs, fence, g2.proximity, &g2.beacon}; # else AC_Avoid avoid{ahrs, fence, g2.proximity}; # endif #endif // Rally library #if AC_RALLY == ENABLED AP_Rally_Copter rally{ahrs}; #endif // RSSI AP_RSSI rssi; // Crop Sprayer #if SPRAYER_ENABLED == ENABLED AC_Sprayer sprayer; #endif // Parachute release #if PARACHUTE == ENABLED AP_Parachute parachute{relay}; #endif // Landing Gear Controller AP_LandingGear landinggear; // terrain handling #if AP_TERRAIN_AVAILABLE && AC_TERRAIN AP_Terrain terrain{ahrs, mission, rally}; #endif // Precision Landing #if PRECISION_LANDING == ENABLED AC_PrecLand precland{ahrs}; #endif // Pilot Input Management Library // Only used for Helicopter for now #if FRAME_CONFIG == HELI_FRAME AC_InputManager_Heli input_manager; #endif #if ADSB_ENABLED == ENABLED AP_ADSB adsb; // avoidance of adsb enabled vehicles (normally manned vehicles) AP_Avoidance_Copter avoidance_adsb{ahrs, adsb}; #endif // last valid RC input time uint32_t last_radio_update_ms; // last esc calibration notification update uint32_t esc_calibration_notify_update_ms; #if VISUAL_ODOMETRY_ENABLED == ENABLED // last visual odometry update time uint32_t visual_odom_last_update_ms; #endif // Top-level logic // setup the var_info table AP_Param param_loader; #if FRAME_CONFIG == HELI_FRAME // Mode filter to reject RC Input glitches. Filter size is 5, and it draws the 4th element, so it can reject 3 low glitches, // and 1 high glitch. This is because any "off" glitches can be highly problematic for a helicopter running an ESC // governor. Even a single "off" frame can cause the rotor to slow dramatically and take a long time to restart. ModeFilterInt16_Size5 rotor_speed_deglitch_filter {4}; // Tradheli flags typedef struct { uint8_t dynamic_flight : 1; // 0 // true if we are moving at a significant speed (used to turn on/off leaky I terms) uint8_t init_targets_on_arming : 1; // 1 // true if we have been disarmed, and need to reset rate controller targets when we arm uint8_t inverted_flight : 1; // 2 // true for inverted flight mode } heli_flags_t; heli_flags_t heli_flags; int16_t hover_roll_trim_scalar_slew; #endif // ground effect detector struct { bool takeoff_expected; bool touchdown_expected; uint32_t takeoff_time_ms; float takeoff_alt_cm; } gndeffect_state; // set when we are upgrading parameters from 3.4 bool upgrading_frame_params; static const AP_Scheduler::Task scheduler_tasks[]; static const AP_Param::Info var_info[]; static const struct LogStructure log_structure[]; enum Failsafe_Action { Failsafe_Action_None = 0, Failsafe_Action_Land = 1, Failsafe_Action_RTL = 2, Failsafe_Action_SmartRTL = 3, Failsafe_Action_SmartRTL_Land = 4, Failsafe_Action_Terminate = 5 }; static constexpr int8_t _failsafe_priorities[] = { Failsafe_Action_Terminate, Failsafe_Action_Land, Failsafe_Action_RTL, Failsafe_Action_SmartRTL_Land, Failsafe_Action_SmartRTL, Failsafe_Action_None, -1 // the priority list must end with a sentinel of -1 }; #define FAILSAFE_LAND_PRIORITY 1 static_assert(_failsafe_priorities[FAILSAFE_LAND_PRIORITY] == Failsafe_Action_Land, "FAILSAFE_LAND_PRIORITY must match the entry in _failsafe_priorities"); static_assert(_failsafe_priorities[ARRAY_SIZE(_failsafe_priorities) - 1] == -1, "_failsafe_priorities is missing the sentinel"); // AP_State.cpp void set_auto_armed(bool b); void set_simple_mode(uint8_t b); void set_failsafe_radio(bool b); void set_failsafe_gcs(bool b); void update_using_interlock(); void set_motor_emergency_stop(bool b); // ArduCopter.cpp void fast_loop(); void rc_loop(); void throttle_loop(); void update_batt_compass(void); void fourhundred_hz_logging(); void ten_hz_logging_loop(); void twentyfive_hz_logging(); void three_hz_loop(); void one_hz_loop(); void update_GPS(void); void init_simple_bearing(); void update_simple_mode(void); void update_super_simple_bearing(bool force_update); void read_AHRS(void); void update_altitude(); // Attitude.cpp float get_pilot_desired_yaw_rate(int16_t stick_angle); void update_throttle_hover(); void set_throttle_takeoff(); float get_pilot_desired_throttle(int16_t throttle_control, float thr_mid = 0.0f); float get_pilot_desired_climb_rate(float throttle_control); float get_non_takeoff_throttle(); float get_surface_tracking_climb_rate(int16_t target_rate, float current_alt_target, float dt); float get_avoidance_adjusted_climbrate(float target_rate); void set_accel_throttle_I_from_pilot_throttle(); void rotate_body_frame_to_NE(float &x, float &y); uint16_t get_pilot_speed_dn(); #if ADSB_ENABLED == ENABLED // avoidance_adsb.cpp void avoidance_adsb_update(void); #endif // baro_ground_effect.cpp void update_ground_effect_detector(void); // capabilities.cpp void init_capabilities(void); // commands.cpp void update_home_from_EKF(); void set_home_to_current_location_inflight(); bool set_home_to_current_location(bool lock); bool set_home(const Location& loc, bool lock); bool far_from_EKF_origin(const Location& loc); // compassmot.cpp MAV_RESULT mavlink_compassmot(mavlink_channel_t chan); // crash_check.cpp void crash_check(); void parachute_check(); void parachute_release(); void parachute_manual_release(); // ekf_check.cpp void ekf_check(); bool ekf_over_threshold(); void failsafe_ekf_event(); void failsafe_ekf_off_event(void); void check_ekf_reset(); // esc_calibration.cpp void esc_calibration_startup_check(); void esc_calibration_passthrough(); void esc_calibration_auto(); void esc_calibration_notify(); // events.cpp void failsafe_radio_on_event(); void failsafe_radio_off_event(); void handle_battery_failsafe(const char* type_str, const int8_t action); void failsafe_gcs_check(); void failsafe_gcs_off_event(void); void failsafe_terrain_check(); void failsafe_terrain_set_status(bool data_ok); void failsafe_terrain_on_event(); void gpsglitch_check(); void set_mode_RTL_or_land_with_pause(mode_reason_t reason); void set_mode_SmartRTL_or_RTL(mode_reason_t reason); void set_mode_SmartRTL_or_land_with_pause(mode_reason_t reason); bool should_disarm_on_failsafe(); void update_events(); // failsafe.cpp void failsafe_enable(); void failsafe_disable(); #if ADVANCED_FAILSAFE == ENABLED void afs_fs_check(void); #endif // fence.cpp void fence_check(); void fence_send_mavlink_status(mavlink_channel_t chan); // GCS_Mavlink.cpp void gcs_send_heartbeat(void); void gcs_send_deferred(void); void send_fence_status(mavlink_channel_t chan); void send_extended_status1(mavlink_channel_t chan); void send_nav_controller_output(mavlink_channel_t chan); void send_rpm(mavlink_channel_t chan); void send_pid_tuning(mavlink_channel_t chan); void gcs_data_stream_send(void); void gcs_check_input(void); // heli.cpp void heli_init(); void check_dynamic_flight(void); void update_heli_control_dynamics(void); void heli_update_landing_swash(); void heli_update_rotor_speed_targets(); // inertia.cpp void read_inertia(); // landing_detector.cpp void update_land_and_crash_detectors(); void update_land_detector(); void set_land_complete(bool b); void set_land_complete_maybe(bool b); void update_throttle_thr_mix(); // landing_gear.cpp void landinggear_update(); // Log.cpp void Log_Write_Optflow(); void Log_Write_Control_Tuning(); void Log_Write_Performance(); void Log_Write_Attitude(); void Log_Write_EKF_POS(); void Log_Write_MotBatt(); void Log_Write_Event(uint8_t id); void Log_Write_Data(uint8_t id, int32_t value); void Log_Write_Data(uint8_t id, uint32_t value); void Log_Write_Data(uint8_t id, int16_t value); void Log_Write_Data(uint8_t id, uint16_t value); void Log_Write_Data(uint8_t id, float value); void Log_Write_Error(uint8_t sub_system, uint8_t error_code); void Log_Write_Parameter_Tuning(uint8_t param, float tuning_val, int16_t control_in, int16_t tune_low, int16_t tune_high); void Log_Sensor_Health(); #if FRAME_CONFIG == HELI_FRAME void Log_Write_Heli(void); #endif void Log_Write_Precland(); void Log_Write_GuidedTarget(uint8_t target_type, const Vector3f& pos_target, const Vector3f& vel_target); void Log_Write_Vehicle_Startup_Messages(); void log_init(void); // mode.cpp bool set_mode(control_mode_t mode, mode_reason_t reason); void update_flight_mode(); void notify_flight_mode(); // mode_land.cpp void set_mode_land_with_pause(mode_reason_t reason); bool landing_with_GPS(); // motor_test.cpp void motor_test_output(); bool mavlink_motor_test_check(mavlink_channel_t chan, bool check_rc); MAV_RESULT mavlink_motor_test_start(mavlink_channel_t chan, uint8_t motor_seq, uint8_t throttle_type, uint16_t throttle_value, float timeout_sec, uint8_t motor_count); void motor_test_stop(); // motors.cpp void arm_motors_check(); void auto_disarm_check(); bool init_arm_motors(bool arming_from_gcs, bool do_arming_checks=true); void init_disarm_motors(); void motors_output(); void lost_vehicle_check(); // navigation.cpp void run_nav_updates(void); int32_t home_bearing(); uint32_t home_distance(); // Parameters.cpp void load_parameters(void); void convert_pid_parameters(void); // position_vector.cpp Vector3f pv_location_to_vector(const Location& loc); float pv_alt_above_origin(float alt_above_home_cm); float pv_alt_above_home(float alt_above_origin_cm); float pv_distance_to_home_cm(const Vector3f &destination); // precision_landing.cpp void init_precland(); void update_precland(); // radio.cpp void default_dead_zones(); void init_rc_in(); void init_rc_out(); void enable_motor_output(); void read_radio(); void set_throttle_and_failsafe(uint16_t throttle_pwm); void set_throttle_zero_flag(int16_t throttle_control); void radio_passthrough_to_motors(); int16_t get_throttle_mid(void); // sensors.cpp void read_barometer(void); void init_rangefinder(void); void read_rangefinder(void); bool rangefinder_alt_ok(); void rpm_update(); void init_compass(); void compass_accumulate(void); void init_optflow(); void update_optical_flow(void); void compass_cal_update(void); void accel_cal_update(void); void init_proximity(); void update_proximity(); void update_sensor_status_flags(void); void init_visual_odom(); void update_visual_odom(); void winch_init(); void winch_update(); // setup.cpp void report_compass(); void print_blanks(int16_t num); void print_divider(void); void print_enabled(bool b); void report_version(); // switches.cpp void read_control_switch(); bool check_if_auxsw_mode_used(uint8_t auxsw_mode_check); bool check_duplicate_auxsw(void); void reset_control_switch(); bool read_3pos_switch(uint8_t chan, uint8_t &ret) const WARN_IF_UNUSED; void read_aux_switches(); void init_aux_switches(); void init_aux_switch_function(int8_t ch_option, uint8_t ch_flag); void do_aux_switch_function(int8_t ch_function, uint8_t ch_flag); bool debounce_aux_switch(uint8_t chan, uint8_t ch_flag); void save_trim(); void auto_trim(); // system.cpp void init_ardupilot(); void startup_INS_ground(); bool position_ok(); bool ekf_position_ok(); bool optflow_position_ok(); void update_auto_armed(); bool should_log(uint32_t mask); void set_default_frame_class(); MAV_TYPE get_frame_mav_type(); const char* get_frame_string(); void allocate_motors(void); void auto_takeoff_set_start_alt(void); void auto_takeoff_attitude_run(float target_yaw_rate); // terrain.cpp void terrain_update(); void terrain_logging(); bool terrain_use(); // tuning.cpp void tuning(); // UserCode.cpp void userhook_init(); void userhook_FastLoop(); void userhook_50Hz(); void userhook_MediumLoop(); void userhook_SlowLoop(); void userhook_SuperSlowLoop(); void userhook_auxSwitch1(uint8_t ch_flag); void userhook_auxSwitch2(uint8_t ch_flag); void userhook_auxSwitch3(uint8_t ch_flag); #include "mode.h" Mode *flightmode; #if MODE_ACRO_ENABLED == ENABLED #if FRAME_CONFIG == HELI_FRAME ModeAcro_Heli mode_acro; #else ModeAcro mode_acro; #endif #endif ModeAltHold mode_althold; #if MODE_AUTO_ENABLED == ENABLED ModeAuto mode_auto; #endif #if AUTOTUNE_ENABLED == ENABLED ModeAutoTune mode_autotune; #endif #if MODE_BRAKE_ENABLED == ENABLED ModeBrake mode_brake; #endif #if MODE_CIRCLE_ENABLED == ENABLED ModeCircle mode_circle; #endif #if MODE_DRIFT_ENABLED == ENABLED ModeDrift mode_drift; #endif ModeFlip mode_flip; #if MODE_FOLLOW_ENABLED == ENABLED ModeFollow mode_follow; #endif #if MODE_GUIDED_ENABLED == ENABLED ModeGuided mode_guided; #endif ModeLand mode_land; #if MODE_LOITER_ENABLED == ENABLED ModeLoiter mode_loiter; #endif #if MODE_POSHOLD_ENABLED == ENABLED ModePosHold mode_poshold; #endif #if MODE_RTL_ENABLED == ENABLED ModeRTL mode_rtl; #endif #if FRAME_CONFIG == HELI_FRAME ModeStabilize_Heli mode_stabilize; #else ModeStabilize mode_stabilize; #endif #if MODE_SPORT_ENABLED == ENABLED ModeSport mode_sport; #endif #if ADSB_ENABLED == ENABLED ModeAvoidADSB mode_avoid_adsb; #endif #if MODE_THROW_ENABLED == ENABLED ModeThrow mode_throw; #endif #if MODE_GUIDED_NOGPS_ENABLED == ENABLED ModeGuidedNoGPS mode_guided_nogps; #endif #if MODE_SMARTRTL_ENABLED == ENABLED ModeSmartRTL mode_smartrtl; #endif #if !HAL_MINIMIZE_FEATURES && OPTFLOW == ENABLED ModeFlowHold mode_flowhold; #endif // mode.cpp Mode *mode_from_mode_num(const uint8_t mode); void exit_mode(Mode *&old_flightmode, Mode *&new_flightmode); public: void mavlink_delay_cb(); // GCS_Mavlink.cpp void failsafe_check(); // failsafe.cpp }; extern const AP_HAL::HAL& hal; extern Copter copter; using AP_HAL::millis; using AP_HAL::micros;