ardupilot/Rover/mode.h

903 lines
33 KiB
C++

#pragma once
#include "Rover.h"
// pre-define ModeRTL so Auto can appear higher in this file
class ModeRTL;
class Mode
{
public:
// Auto Pilot modes
// ----------------
enum Number : uint8_t {
MANUAL = 0,
ACRO = 1,
STEERING = 3,
HOLD = 4,
LOITER = 5,
FOLLOW = 6,
SIMPLE = 7,
#if MODE_DOCK_ENABLED == ENABLED
DOCK = 8,
#endif
CIRCLE = 9,
AUTO = 10,
RTL = 11,
SMART_RTL = 12,
GUIDED = 15,
INITIALISING = 16,
};
// Constructor
Mode();
// do not allow copying
CLASS_NO_COPY(Mode);
// enter this mode, returns false if we failed to enter
bool enter();
// perform any cleanups required:
void exit();
// returns a unique number specific to this mode
virtual uint32_t mode_number() const = 0;
// returns short text name (up to 4 bytes)
virtual const char *name4() const = 0;
//
// methods that sub classes should override to affect movement of the vehicle in this mode
//
// convert user input to targets, implement high level control for this mode
virtual void update() = 0;
//
// attributes of the mode
//
// return if in non-manual mode : Auto, Guided, RTL, SmartRTL
virtual bool is_autopilot_mode() const { return false; }
// return if external control is allowed in this mode (Guided or Guided-within-Auto)
virtual bool in_guided_mode() const { return false; }
// returns true if vehicle can be armed or disarmed from the transmitter in this mode
virtual bool allows_arming_from_transmitter() { return !is_autopilot_mode(); }
// returns false if vehicle cannot be armed in this mode
virtual bool allows_arming() const { return true; }
bool allows_stick_mixing() const { return is_autopilot_mode(); }
//
// attributes for mavlink system status reporting
//
// returns true if any RC input is used
virtual bool has_manual_input() const { return false; }
// true if heading is controlled
virtual bool attitude_stabilized() const { return true; }
// true if mode requires position and/or velocity estimate
virtual bool requires_position() const { return true; }
virtual bool requires_velocity() const { return true; }
// return heading (in degrees) and cross track error (in meters) for reporting to ground station (NAV_CONTROLLER_OUTPUT message)
virtual float wp_bearing() const;
virtual float nav_bearing() const;
virtual float crosstrack_error() const;
virtual float get_desired_lat_accel() const;
// get speed error in m/s, not currently supported
float speed_error() const { return 0.0f; }
//
// navigation methods
//
// return distance (in meters) to destination
virtual float get_distance_to_destination() const { return 0.0f; }
// return desired location (used in Guided, Auto, RTL, etc)
// return true on success, false if there is no valid destination
virtual bool get_desired_location(Location& destination) const WARN_IF_UNUSED { return false; }
// set desired location (used in Guided, Auto)
// set next_destination (if known). If not provided vehicle stops at destination
virtual bool set_desired_location(const Location &destination, Location next_destination = Location()) WARN_IF_UNUSED;
// true if vehicle has reached desired location. defaults to true because this is normally used by missions and we do not want the mission to become stuck
virtual bool reached_destination() const { return true; }
// get default speed for this mode (held in CRUISE_SPEED, WP_SPEED or RTL_SPEED)
// rtl argument should be true if called from RTL or SmartRTL modes (handled here to avoid duplication)
float get_speed_default(bool rtl = false) const;
// set desired speed in m/s
virtual bool set_desired_speed(float speed) { return false; }
// execute the mission in reverse (i.e. backing up)
void set_reversed(bool value);
// handle tacking request (from auxiliary switch) in sailboats
virtual void handle_tack_request();
protected:
// subclasses override this to perform checks before entering the mode
virtual bool _enter() { return true; }
// subclasses override this to perform any required cleanup when exiting the mode
virtual void _exit() { return; }
// decode pilot steering and throttle inputs and return in steer_out and throttle_out arguments
// steering_out is in the range -4500 ~ +4500 with positive numbers meaning rotate clockwise
// throttle_out is in the range -100 ~ +100
void get_pilot_desired_steering_and_throttle(float &steering_out, float &throttle_out);
// decode pilot input steering and return steering_out and speed_out (in m/s)
void get_pilot_desired_steering_and_speed(float &steering_out, float &speed_out);
// decode pilot lateral movement input and return in lateral_out argument
void get_pilot_desired_lateral(float &lateral_out);
// decode pilot's input and return heading_out (in cd) and speed_out (in m/s)
void get_pilot_desired_heading_and_speed(float &heading_out, float &speed_out);
// decode pilot roll and pitch inputs and return in roll_out and pitch_out arguments
// outputs are in the range -1 to +1
void get_pilot_desired_roll_and_pitch(float &roll_out, float &pitch_out);
// decode pilot height inputs and return in height_out arguments
// outputs are in the range -1 to +1
void get_pilot_desired_walking_height(float &walking_height_out);
// high level call to navigate to waypoint
void navigate_to_waypoint();
// calculate steering output given a turn rate
// desired turn rate in radians/sec. Positive to the right.
void calc_steering_from_turn_rate(float turn_rate);
// calculate steering angle given a desired lateral acceleration
void calc_steering_from_lateral_acceleration(float lat_accel, bool reversed = false);
// calculate steering output to drive towards desired heading
// rate_max is a maximum turn rate in deg/s. set to zero to use default turn rate limits
void calc_steering_to_heading(float desired_heading_cd, float rate_max_degs = 0.0f);
// calculates the amount of throttle that should be output based
// on things like proximity to corners and current speed
virtual void calc_throttle(float target_speed, bool avoidance_enabled);
// performs a controlled stop. returns true once vehicle has stopped
bool stop_vehicle();
// estimate maximum vehicle speed (in m/s)
// cruise_speed is in m/s, cruise_throttle should be in the range -1 to +1
float calc_speed_max(float cruise_speed, float cruise_throttle) const;
// calculate pilot input to nudge speed up or down
// target_speed should be in meters/sec
// reversed should be true if the vehicle is intentionally backing up which allows the pilot to increase the backing up speed by pulling the throttle stick down
float calc_speed_nudge(float target_speed, bool reversed);
protected:
// decode pilot steering and throttle inputs and return in steer_out and throttle_out arguments
// steering_out is in the range -4500 ~ +4500 with positive numbers meaning rotate clockwise
// throttle_out is in the range -100 ~ +100
void get_pilot_input(float &steering_out, float &throttle_out);
void set_steering(float steering_value);
// references to avoid code churn:
class AP_AHRS &ahrs;
class Parameters &g;
class ParametersG2 &g2;
class RC_Channel *&channel_steer;
class RC_Channel *&channel_throttle;
class RC_Channel *&channel_lateral;
class RC_Channel *&channel_roll;
class RC_Channel *&channel_pitch;
class RC_Channel *&channel_walking_height;
class AR_AttitudeControl &attitude_control;
// private members for waypoint navigation
float _distance_to_destination; // distance from vehicle to final destination in meters
bool _reached_destination; // true once the vehicle has reached the destination
float _desired_yaw_cd; // desired yaw in centi-degrees. used in Auto, Guided and Loiter
};
class ModeAcro : public Mode
{
public:
uint32_t mode_number() const override { return ACRO; }
const char *name4() const override { return "ACRO"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
// acro mode requires a velocity estimate for non skid-steer rovers
bool requires_position() const override { return false; }
bool requires_velocity() const override;
// sailboats in acro mode support user manually initiating tacking from transmitter
void handle_tack_request() override;
};
class ModeAuto : public Mode
{
public:
uint32_t mode_number() const override { return AUTO; }
const char *name4() const override { return "AUTO"; }
// methods that affect movement of the vehicle in this mode
void update() override;
void calc_throttle(float target_speed, bool avoidance_enabled) override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
// return if external control is allowed in this mode (Guided or Guided-within-Auto)
bool in_guided_mode() const override { return _submode == Auto_Guided || _submode == Auto_NavScriptTime; }
// return heading (in degrees) and cross track error (in meters) for reporting to ground station (NAV_CONTROLLER_OUTPUT message)
float wp_bearing() const override;
float nav_bearing() const override;
float crosstrack_error() const override;
float get_desired_lat_accel() const override;
// return distance (in meters) to destination
float get_distance_to_destination() const override;
// get or set desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED;
bool set_desired_location(const Location &destination, Location next_destination = Location()) override WARN_IF_UNUSED;
bool reached_destination() const override;
// set desired speed in m/s
bool set_desired_speed(float speed) override;
// start RTL (within auto)
void start_RTL();
// lua accessors for nav script time support
bool nav_script_time(uint16_t &id, uint8_t &cmd, float &arg1, float &arg2, int16_t &arg3, int16_t &arg4);
void nav_script_time_done(uint16_t id);
AP_Mission mission{
FUNCTOR_BIND_MEMBER(&ModeAuto::start_command, bool, const AP_Mission::Mission_Command&),
FUNCTOR_BIND_MEMBER(&ModeAuto::verify_command_callback, bool, const AP_Mission::Mission_Command&),
FUNCTOR_BIND_MEMBER(&ModeAuto::exit_mission, void)};
enum Mis_Done_Behave {
MIS_DONE_BEHAVE_HOLD = 0,
MIS_DONE_BEHAVE_LOITER = 1,
MIS_DONE_BEHAVE_ACRO = 2,
MIS_DONE_BEHAVE_MANUAL = 3
};
protected:
bool _enter() override;
void _exit() override;
enum AutoSubMode {
Auto_WP, // drive to a given location
Auto_HeadingAndSpeed, // turn to a given heading
Auto_RTL, // perform RTL within auto mode
Auto_Loiter, // perform Loiter within auto mode
Auto_Guided, // handover control to external navigation system from within auto mode
Auto_Stop, // stop the vehicle as quickly as possible
Auto_NavScriptTime, // accept targets from lua scripts while NAV_SCRIPT_TIME commands are executing
Auto_Circle, // circle a given location
} _submode;
private:
bool check_trigger(void);
bool start_loiter();
void start_guided(const Location& target_loc);
void start_stop();
void send_guided_position_target();
bool start_command(const AP_Mission::Mission_Command& cmd);
void exit_mission();
bool verify_command_callback(const AP_Mission::Mission_Command& cmd);
bool verify_command(const AP_Mission::Mission_Command& cmd);
void do_RTL(void);
bool do_nav_wp(const AP_Mission::Mission_Command& cmd, bool always_stop_at_destination);
void do_nav_guided_enable(const AP_Mission::Mission_Command& cmd);
void do_nav_set_yaw_speed(const AP_Mission::Mission_Command& cmd);
void do_nav_delay(const AP_Mission::Mission_Command& cmd);
bool verify_nav_delay(const AP_Mission::Mission_Command& cmd);
bool verify_nav_wp(const AP_Mission::Mission_Command& cmd);
bool verify_RTL() const;
bool verify_loiter_unlimited(const AP_Mission::Mission_Command& cmd);
bool verify_loiter_time(const AP_Mission::Mission_Command& cmd);
bool verify_nav_guided_enable(const AP_Mission::Mission_Command& cmd);
bool verify_nav_set_yaw_speed();
bool do_circle(const AP_Mission::Mission_Command& cmd);
bool verify_circle(const AP_Mission::Mission_Command& cmd);
void do_wait_delay(const AP_Mission::Mission_Command& cmd);
void do_within_distance(const AP_Mission::Mission_Command& cmd);
bool verify_wait_delay();
bool verify_within_distance();
void do_change_speed(const AP_Mission::Mission_Command& cmd);
void do_set_home(const AP_Mission::Mission_Command& cmd);
void do_set_reverse(const AP_Mission::Mission_Command& cmd);
void do_guided_limits(const AP_Mission::Mission_Command& cmd);
#if AP_SCRIPTING_ENABLED
void do_nav_script_time(const AP_Mission::Mission_Command& cmd);
bool verify_nav_script_time();
#endif
bool waiting_to_start; // true if waiting for EKF origin before starting mission
bool auto_triggered; // true when auto has been triggered to start
// HeadingAndSpeed sub mode variables
float _desired_speed; // desired speed in HeadingAndSpeed submode
bool _reached_heading; // true when vehicle has reached desired heading in TurnToHeading sub mode
// Loiter control
uint16_t loiter_duration; // How long we should loiter at the nav_waypoint (time in seconds)
uint32_t loiter_start_time; // How long have we been loitering - The start time in millis
bool previously_reached_wp; // set to true if we have EVER reached the waypoint
// Guided-within-Auto variables
struct {
Location loc; // location target sent to external navigation
bool valid; // true if loc is valid
uint32_t last_sent_ms; // system time that target was last sent to offboard navigation
} guided_target;
// Conditional command
// A value used in condition commands (eg delay, change alt, etc.)
// For example in a change altitude command, it is the altitude to change to.
int32_t condition_value;
// A starting value used to check the status of a conditional command.
// For example in a delay command the condition_start records that start time for the delay
int32_t condition_start;
// Delay the next navigation command
uint32_t nav_delay_time_max_ms; // used for delaying the navigation commands
uint32_t nav_delay_time_start_ms;
#if AP_SCRIPTING_ENABLED
// nav_script_time command variables
struct {
bool done; // true once lua script indicates it has completed
uint16_t id; // unique id to avoid race conditions between commands and lua scripts
uint32_t start_ms; // system time nav_script_time command was received (used for timeout)
uint8_t command; // command number provided by mission command
uint8_t timeout_s; // timeout (in seconds) provided by mission command
float arg1; // 1st argument provided by mission command
float arg2; // 2nd argument provided by mission command
int16_t arg3; // 3rd argument provided by mission command
int16_t arg4; // 4th argument provided by mission command
} nav_scripting;
#endif
// Mission change detector
AP_Mission_ChangeDetector mis_change_detector;
};
class ModeCircle : public Mode
{
public:
// need a constructor for parameters
ModeCircle();
// Does not allow copies
CLASS_NO_COPY(ModeCircle);
uint32_t mode_number() const override { return CIRCLE; }
const char *name4() const override { return "CIRC"; }
// initialise with specific center location, radius (in meters) and direction
// replaces use of _enter when initialised from within Auto mode
bool set_center(const Location& center_loc, float radius_m, bool dir_ccw);
// methods that affect movement of the vehicle in this mode
void update() override;
bool is_autopilot_mode() const override { return true; }
// return desired heading (in degrees) and cross track error (in meters) for reporting to ground station (NAV_CONTROLLER_OUTPUT message)
float wp_bearing() const override;
float nav_bearing() const override;
float crosstrack_error() const override { return dist_to_edge_m; }
float get_desired_lat_accel() const override;
// set desired speed in m/s
bool set_desired_speed(float speed_ms) override;
// return distance (in meters) to destination
float get_distance_to_destination() const override { return _distance_to_destination; }
// get or set desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED;
// return total angle in radians that vehicle has circled
// fabsf is used so that full rotations in either direction are counted
float get_angle_total_rad() const { return fabsf(angle_total_rad); }
static const struct AP_Param::GroupInfo var_info[];
protected:
AP_Float radius; // circle radius in meters
AP_Float speed; // vehicle speed in m/s. If zero uses WP_SPEED
AP_Int8 direction; // direction 0:clockwise, 1:counter-clockwise
// initialise mode
bool _enter() override;
// initialise target_yaw_rad using the vehicle's position and yaw
// if there is no current position estimate target_yaw_rad is set to vehicle yaw
void init_target_yaw_rad();
// limit config speed so that lateral acceleration is within limits
// outputs warning to user if speed is reduced
void check_config_speed();
// ensure config radius is no smaller then vehicle's TURN_RADIUS
// radius is increased if necessary and warning is output to the user
void check_config_radius();
// enum for Direction parameter
enum class Direction {
CW = 0,
CCW = 1
};
// local members
struct {
Location center_loc; // circle center as a Location
Vector2f center_pos; // circle center as an offset (in meters) from the EKF origin
float radius; // circle radius
float speed; // desired speed around circle in m/s
Direction dir; // direction, 0:clockwise, 1:counter-clockwise
} config;
struct {
float speed; // vehicle's target speed around circle in m/s
float yaw_rad; // earth-frame angle of tarrget point on the circle
Vector2p pos; // latest position target sent to position controller
Vector2f vel; // latest velocity target sent to position controller
Vector2f accel; // latest accel target sent to position controller
} target;
float angle_total_rad; // total angle in radians that vehicle has circled
bool reached_edge; // true once vehicle has reached edge of circle
float dist_to_edge_m; // distance to edge of circle in meters (equivalent to crosstrack error)
};
class ModeGuided : public Mode
{
public:
uint32_t mode_number() const override { return GUIDED; }
const char *name4() const override { return "GUID"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
// return if external control is allowed in this mode (Guided or Guided-within-Auto)
bool in_guided_mode() const override { return true; }
// return heading (in degrees) and cross track error (in meters) for reporting to ground station (NAV_CONTROLLER_OUTPUT message)
float wp_bearing() const override;
float nav_bearing() const override;
float crosstrack_error() const override;
float get_desired_lat_accel() const override;
// return distance (in meters) to destination
float get_distance_to_destination() const override;
// return true if vehicle has reached destination
bool reached_destination() const override;
// set desired speed in m/s
bool set_desired_speed(float speed) override;
// get or set desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED;
bool set_desired_location(const Location &destination, Location next_destination = Location()) override WARN_IF_UNUSED;
// set desired heading and speed
void set_desired_heading_and_speed(float yaw_angle_cd, float target_speed);
// set desired heading-delta, turn-rate and speed
void set_desired_heading_delta_and_speed(float yaw_delta_cd, float target_speed);
void set_desired_turn_rate_and_speed(float turn_rate_cds, float target_speed);
// set steering and throttle (-1 to +1). Only called from scripts
void set_steering_and_throttle(float steering, float throttle);
// vehicle start loiter
bool start_loiter();
// start stopping
void start_stop();
// guided limits
void limit_set(uint32_t timeout_ms, float horiz_max);
void limit_clear();
void limit_init_time_and_location();
bool limit_breached() const;
protected:
enum GuidedMode {
Guided_WP,
Guided_HeadingAndSpeed,
Guided_TurnRateAndSpeed,
Guided_Loiter,
Guided_SteeringAndThrottle,
Guided_Stop
};
// enum for GUID_OPTIONS parameter
enum class Options : int32_t {
SCurvesUsedForNavigation = (1U << 6)
};
bool _enter() override;
// returns true if GUID_OPTIONS bit set to use scurve navigation instead of position controller input shaping
// scurves provide path planning and object avoidance but cannot handle fast updates to the destination (for fast updates use position controller input shaping)
bool use_scurves_for_navigation() const;
GuidedMode _guided_mode; // stores which GUIDED mode the vehicle is in
// attitude control
bool have_attitude_target; // true if we have a valid attitude target
uint32_t _des_att_time_ms; // system time last call to set_desired_attitude was made (used for timeout)
float _desired_yaw_rate_cds;// target turn rate centi-degrees per second
bool send_notification; // used to send one time notification to ground station
float _desired_speed; // desired speed used only in HeadingAndSpeed submode
// direct steering and throttle control
bool _have_strthr; // true if we have a valid direct steering and throttle inputs
uint32_t _strthr_time_ms; // system time last call to set_steering_and_throttle was made (used for timeout)
float _strthr_steering; // direct steering input in the range -1 to +1
float _strthr_throttle; // direct throttle input in the range -1 to +1
// limits
struct {
uint32_t timeout_ms;// timeout from the time that guided is invoked
float horiz_max; // horizontal position limit in meters from where guided mode was initiated (0 = no limit)
uint32_t start_time_ms; // system time in milliseconds that control was handed to the external computer
Location start_loc; // starting location for checking horiz_max limit
} limit;
};
class ModeHold : public Mode
{
public:
uint32_t mode_number() const override { return HOLD; }
const char *name4() const override { return "HOLD"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes for mavlink system status reporting
bool attitude_stabilized() const override { return false; }
// hold mode does not require position or velocity estimate
bool requires_position() const override { return false; }
bool requires_velocity() const override { return false; }
};
class ModeLoiter : public Mode
{
public:
uint32_t mode_number() const override { return LOITER; }
const char *name4() const override { return "LOIT"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
// return desired heading (in degrees) and cross track error (in meters) for reporting to ground station (NAV_CONTROLLER_OUTPUT message)
float wp_bearing() const override { return _desired_yaw_cd * 0.01f; }
float nav_bearing() const override { return _desired_yaw_cd * 0.01f; }
float crosstrack_error() const override { return 0.0f; }
// return desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED;
// return distance (in meters) to destination
float get_distance_to_destination() const override { return _distance_to_destination; }
protected:
bool _enter() override;
Location _destination; // target location to hold position around
float _desired_speed; // desired speed (ramped down from initial speed to zero)
};
class ModeManual : public Mode
{
public:
uint32_t mode_number() const override { return MANUAL; }
const char *name4() const override { return "MANU"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
bool attitude_stabilized() const override { return false; }
// manual mode does not require position or velocity estimate
bool requires_position() const override { return false; }
bool requires_velocity() const override { return false; }
protected:
void _exit() override;
};
class ModeRTL : public Mode
{
public:
uint32_t mode_number() const override { return RTL; }
const char *name4() const override { return "RTL"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
// do not allow arming from this mode
bool allows_arming() const override { return false; }
// return desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED;
// return distance (in meters) to destination
float get_distance_to_destination() const override { return _distance_to_destination; }
bool reached_destination() const override;
// set desired speed in m/s
bool set_desired_speed(float speed) override;
protected:
bool _enter() override;
bool send_notification; // used to send one time notification to ground station
bool _loitering; // true if loitering at end of RTL
};
class ModeSmartRTL : public Mode
{
public:
uint32_t mode_number() const override { return SMART_RTL; }
const char *name4() const override { return "SRTL"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
// do not allow arming from this mode
bool allows_arming() const override { return false; }
// return desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED;
// return distance (in meters) to destination
float get_distance_to_destination() const override { return _distance_to_destination; }
bool reached_destination() const override { return smart_rtl_state == SmartRTL_StopAtHome; }
// set desired speed in m/s
bool set_desired_speed(float speed) override;
// save current position for use by the smart_rtl flight mode
void save_position();
protected:
// Safe RTL states
enum SmartRTLState {
SmartRTL_WaitForPathCleanup,
SmartRTL_PathFollow,
SmartRTL_StopAtHome,
SmartRTL_Failure
} smart_rtl_state;
bool _enter() override;
bool _load_point;
bool _loitering; // true if loitering at end of SRTL
};
class ModeSteering : public Mode
{
public:
uint32_t mode_number() const override { return STEERING; }
const char *name4() const override { return "STER"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
// steering requires velocity but not position
bool requires_position() const override { return false; }
bool requires_velocity() const override { return true; }
// return desired lateral acceleration
float get_desired_lat_accel() const override { return _desired_lat_accel; }
private:
float _desired_lat_accel; // desired lateral acceleration calculated from pilot steering input
};
class ModeInitializing : public Mode
{
public:
uint32_t mode_number() const override { return INITIALISING; }
const char *name4() const override { return "INIT"; }
// methods that affect movement of the vehicle in this mode
void update() override { }
// do not allow arming from this mode
bool allows_arming() const override { return false; }
// attributes for mavlink system status reporting
bool has_manual_input() const override { return true; }
bool attitude_stabilized() const override { return false; }
protected:
bool _enter() override { return false; };
};
#if MODE_FOLLOW_ENABLED == ENABLED
class ModeFollow : public Mode
{
public:
uint32_t mode_number() const override { return FOLLOW; }
const char *name4() const override { return "FOLL"; }
// methods that affect movement of the vehicle in this mode
void update() override;
// attributes of the mode
bool is_autopilot_mode() const override { return true; }
// return desired heading (in degrees) and cross track error (in meters) for reporting to ground station (NAV_CONTROLLER_OUTPUT message)
float wp_bearing() const override;
float nav_bearing() const override { return wp_bearing(); }
float crosstrack_error() const override { return 0.0f; }
// return desired location
bool get_desired_location(Location& destination) const override WARN_IF_UNUSED { return false; }
// return distance (in meters) to destination
float get_distance_to_destination() const override;
// set desired speed in m/s
bool set_desired_speed(float speed) override;
protected:
bool _enter() override;
void _exit() override;
float _desired_speed; // desired speed in m/s
};
#endif
class ModeSimple : public Mode
{
public:
uint32_t mode_number() const override { return SIMPLE; }
const char *name4() const override { return "SMPL"; }
// methods that affect movement of the vehicle in this mode
void update() override;
void init_heading();
// simple type enum used for SIMPLE_TYPE parameter
enum simple_type {
Simple_InitialHeading = 0,
Simple_CardinalDirections = 1,
};
private:
float _initial_heading_cd; // vehicle heading (in centi-degrees) at moment vehicle was armed
float _desired_heading_cd; // latest desired heading (in centi-degrees) from pilot
};
#if MODE_DOCK_ENABLED == ENABLED
class ModeDock : public Mode
{
public:
// need a constructor for parameters
ModeDock(void);
// Does not allow copies
CLASS_NO_COPY(ModeDock);
uint32_t mode_number() const override { return DOCK; }
const char *name4() const override { return "DOCK"; }
// methods that affect movement of the vehicle in this mode
void update() override;
bool is_autopilot_mode() const override { return true; }
// return distance (in meters) to destination
float get_distance_to_destination() const override { return _distance_to_destination; }
static const struct AP_Param::GroupInfo var_info[];
protected:
AP_Float speed; // dock mode speed
AP_Float desired_dir; // desired direction of approach
AP_Int8 hdg_corr_enable; // enable heading correction
AP_Float hdg_corr_weight; // heading correction weight
AP_Float stopping_dist; // how far away from the docking target should we start stopping
bool _enter() override;
// return reduced speed of vehicle based on error in position and current distance from the dock
float apply_slowdown(float desired_speed);
// calculate position of dock relative to the vehicle
bool calc_dock_pos_rel_vehicle_NE(Vector2f &dock_pos_rel_vehicle) const;
// we force the vehicle to use real dock target vector when this much close to the docking station
const float _force_real_target_limit_cm = 300.0f;
// acceptable lateral error in vehicle's position with respect to dock. This is used while slowing down the vehicle
const float _acceptable_pos_error_cm = 20.0f;
Vector2f _dock_pos_rel_origin_cm; // position vector towards docking target relative to ekf origin
Vector2f _desired_heading_NE; // unit vector in desired direction of docking
bool _docking_complete = false; // flag to mark docking complete when we are close enough to the dock
bool _loitering = false; // true if we are loitering after mission completion
};
#endif