ardupilot/libraries/APM_Control/AR_PosControl.h

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#pragma once
#include <AP_Common/AP_Common.h>
#include <APM_Control/AR_AttitudeControl.h>
#include <AC_PID/AC_P_2D.h> // P library (2-axis)
#include <AC_PID/AC_PID_2D.h> // PID library (2-axis)
class AR_PosControl {
public:
// constructor
AR_PosControl(AR_AttitudeControl& atc);
// do not allow copying
CLASS_NO_COPY(AR_PosControl);
static AR_PosControl *get_singleton() { return _singleton; }
// update navigation
void update(float dt);
// true if update has been called recently
bool is_active() const;
// set speed, acceleration and jerk limits
void set_limits(float speed_max, float accel_max, float lat_accel_max, float jerk_max);
// setter to allow vehicle code to provide turn related param values to this library (should be updated regularly)
void set_turn_params(float turn_radius, bool pivot_possible);
// set reversed
void set_reversed(bool reversed) { _reversed = reversed; }
// accessor for _reversed
bool get_reversed() { return _reversed; }
// get limits
float get_speed_max() const { return _speed_max; }
float get_accel_max() const { return _accel_max; }
float get_lat_accel_max() const { return _lat_accel_max; }
float get_jerk_max() const { return _jerk_max; }
// initialise the position controller to the current position, velocity, acceleration and attitude
// this should be called before the input shaping methods are used
// return true on success, false if targets cannot be initialised
bool init();
// adjust position, velocity and acceleration targets smoothly using input shaping
// pos is the target position as an offset from the EKF origin (in meters)
// vel is the target velocity in m/s. accel is the target acceleration in m/s/s
// dt should be the update rate in seconds
// init should be called once before starting to use these methods
void input_pos_target(const Vector2p &pos, float dt);
void input_pos_vel_target(const Vector2p &pos, const Vector2f &vel, float dt);
void input_pos_vel_accel_target(const Vector2p &pos, const Vector2f &vel, const Vector2f &accel, float dt);
// set target position, desired velocity and acceleration. These should be from an externally created path and are not "input shaped"
void set_pos_vel_accel_target(const Vector2p &pos, const Vector2f &vel, const Vector2f &accel);
// get outputs for forward-back speed (in m/s), lateral speed (in m/s) and turn rate (in rad/sec)
float get_desired_speed() const { return _desired_speed; }
float get_desired_turn_rate_rads() const { return _desired_turn_rate_rads; }
float get_desired_lat_accel() const { return _desired_lat_accel; }
// get position target
const Vector2p& get_pos_target() const { return _pos_target; }
// returns desired velocity vector (i.e. feed forward) in m/s in NE frame
Vector2f get_desired_velocity() const;
// return desired acceleration vector in m/s in NE frame
Vector2f get_desired_accel() const;
/// get position error as a vector from the current position to the target position
Vector2p get_pos_error() const;
// get pid controllers
AC_P_2D& get_pos_p() { return _p_pos; }
AC_PID_2D& get_vel_pid() { return _pid_vel; }
// get the slew rate value for velocity. used for oscillation detection in lua scripts
void get_srate(float &velocity_srate);
// write PSC logs
void write_log();
// parameter var table
static const struct AP_Param::GroupInfo var_info[];
private:
static AR_PosControl *_singleton;
// initialise and check for ekf position resets
void init_ekf_xy_reset();
void handle_ekf_xy_reset();
// references
AR_AttitudeControl &_atc; // rover attitude control library
// parameters
AC_P_2D _p_pos; // position P controller to convert distance error to desired velocity
AC_PID_2D _pid_vel; // velocity PID controller to convert velocity error to desired acceleration
// limits
float _speed_max; // maximum forward speed in m/s
float _accel_max; // maximum forward/back acceleration in m/s/s
float _lat_accel_max; // lateral acceleration maximum in m/s/s
float _jerk_max; // maximum jerk in m/s/s/s (used for both forward and lateral input shaping)
float _turn_radius; // vehicle turn radius in meters
// position and velocity targets
Vector2p _pos_target; // position target as an offset (in meters) from the EKF origin
Vector2f _vel_desired; // desired velocity in m/s in NE frame. This is the "feed forward" provided by SCurves
Vector2f _vel_target; // velocity target in m/s in NE frame
Vector2f _accel_desired; // desired accel in m/s/s in NE frame. This is the "feed forward" provided by SCurves
Vector2f _accel_target; // accel target in m/s/s in NE frame
bool _pos_target_valid; // true if _pos_target is valid
bool _vel_desired_valid; // true if _vel_desired is valid
bool _accel_desired_valid; // true if _accel_desired is valid
// variables for navigation
uint32_t _last_update_ms; // system time of last call to update
bool _reversed; // true if vehicle should move in reverse towards target
// main outputs
float _desired_speed; // desired forward_back speed in m/s
float _desired_turn_rate_rads; // desired turn-rate in rad/sec (negative is counter clockwise, positive is clockwise)
float _desired_lat_accel; // desired lateral acceleration (for reporting only)
// ekf reset handling
uint32_t _ekf_xy_reset_ms; // system time of last recorded ekf xy position reset
};