px4-firmware/l1/ecl_l1_pos_controller.h

269 lines
7.8 KiB
C++

/****************************************************************************
*
* Copyright (c) 2013 Estimation and Control Library (ECL). All rights reserved.
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/**
* @file ecl_l1_pos_control.h
* Implementation of L1 position control.
*
*
* Acknowledgements and References:
*
* This implementation has been built for PX4 based on the original
* publication from [1] and does include a lot of the ideas (not code)
* from [2].
*
*
* [1] S. Park, J. Deyst, and J. P. How, "A New Nonlinear Guidance Logic for Trajectory Tracking,"
* Proceedings of the AIAA Guidance, Navigation and Control
* Conference, Aug 2004. AIAA-2004-4900.
*
* [2] Paul Riseborough, Brandon Jones and Andrew Tridgell, L1 control for APM. Aug 2013.
* - Explicit control over frequency and damping
* - Explicit control over track capture angle
* - Ability to use loiter radius smaller than L1 length
* - Modified to use PD control for circle tracking to enable loiter radius less than L1 length
* - Modified to enable period and damping of guidance loop to be set explicitly
* - Modified to provide explicit control over capture angle
*
*/
#ifndef ECL_L1_POS_CONTROLLER_H
#define ECL_L1_POS_CONTROLLER_H
#include <mathlib/mathlib.h>
#include <geo/geo.h>
#include <ecl/ecl.h>
/**
* L1 Nonlinear Guidance Logic
*/
class __EXPORT ECL_L1_Pos_Controller
{
public:
ECL_L1_Pos_Controller() {
_L1_period = 25;
_L1_damping = 0.75f;
}
/**
* The current target bearing
*
* @return bearing angle (-pi..pi, in NED frame)
*/
float nav_bearing();
/**
* Get lateral acceleration demand.
*
* @return Lateral acceleration in m/s^2
*/
float nav_lateral_acceleration_demand();
/**
* Heading error.
*
* The heading error is either compared to the current track
* or to the tangent of the current loiter radius.
*/
float bearing_error();
/**
* Bearing from aircraft to current target.
*
* @return bearing angle (-pi..pi, in NED frame)
*/
float target_bearing();
/**
* Get roll angle setpoint for fixed wing.
*
* @return Roll angle (in NED frame)
*/
float nav_roll();
/**
* Get the current crosstrack error.
*
* @return Crosstrack error in meters.
*/
float crosstrack_error();
/**
* Returns true if the loiter waypoint has been reached
*/
bool reached_loiter_target();
/**
* Returns true if following a circle (loiter)
*/
bool circle_mode() {
return _circle_mode;
}
/**
* Get the switch distance
*
* This is the distance at which the system will
* switch to the next waypoint. This depends on the
* period and damping
*
* @param waypoint_switch_radius The switching radius the waypoint has set.
*/
float switch_distance(float waypoint_switch_radius);
/**
* Navigate between two waypoints
*
* Calling this function with two waypoints results in the
* control outputs to fly to the line segment defined by
* the points and once captured following the line segment.
* This follows the logic in [1].
*
* @return sets _lateral_accel setpoint
*/
void navigate_waypoints(const math::Vector<2> &vector_A, const math::Vector<2> &vector_B, const math::Vector<2> &vector_curr_position,
const math::Vector<2> &ground_speed);
/**
* Navigate on an orbit around a loiter waypoint.
*
* This allow orbits smaller than the L1 length,
* this modification was introduced in [2].
*
* @return sets _lateral_accel setpoint
*/
void navigate_loiter(const math::Vector<2> &vector_A, const math::Vector<2> &vector_curr_position, float radius, int8_t loiter_direction,
const math::Vector<2> &ground_speed_vector);
/**
* Navigate on a fixed bearing.
*
* This only holds a certain direction and does not perform cross
* track correction. Helpful for semi-autonomous modes. Introduced
* by [2].
*
* @return sets _lateral_accel setpoint
*/
void navigate_heading(float navigation_heading, float current_heading, const math::Vector<2> &ground_speed);
/**
* Keep the wings level.
*
* This is typically needed for maximum-lift-demand situations,
* such as takeoff or near stall. Introduced in [2].
*/
void navigate_level_flight(float current_heading);
/**
* Set the L1 period.
*/
void set_l1_period(float period) {
_L1_period = period;
/* calculate the ratio introduced in [2] */
_L1_ratio = 1.0f / M_PI_F * _L1_damping * _L1_period;
/* calculate normalized frequency for heading tracking */
_heading_omega = sqrtf(2.0f) * M_PI_F / _L1_period;
}
/**
* Set the L1 damping factor.
*
* The original publication recommends a default of sqrt(2) / 2 = 0.707
*/
void set_l1_damping(float damping) {
_L1_damping = damping;
/* calculate the ratio introduced in [2] */
_L1_ratio = 1.0f / M_PI_F * _L1_damping * _L1_period;
/* calculate the L1 gain (following [2]) */
_K_L1 = 4.0f * _L1_damping * _L1_damping;
}
/**
* Set the maximum roll angle output in radians
*
*/
void set_l1_roll_limit(float roll_lim_rad) {
_roll_lim_rad = roll_lim_rad;
}
private:
float _lateral_accel; ///< Lateral acceleration setpoint in m/s^2
float _L1_distance; ///< L1 lead distance, defined by period and damping
bool _circle_mode; ///< flag for loiter mode
float _nav_bearing; ///< bearing to L1 reference point
float _bearing_error; ///< bearing error
float _crosstrack_error; ///< crosstrack error in meters
float _target_bearing; ///< the heading setpoint
float _L1_period; ///< L1 tracking period in seconds
float _L1_damping; ///< L1 damping ratio
float _L1_ratio; ///< L1 ratio for navigation
float _K_L1; ///< L1 control gain for _L1_damping
float _heading_omega; ///< Normalized frequency
float _roll_lim_rad; ///<maximum roll angle
/**
* Convert a 2D vector from WGS84 to planar coordinates.
*
* This converts from latitude and longitude to planar
* coordinates with (0,0) being at the position of ref and
* returns a vector in meters towards wp.
*
* @param ref The reference position in WGS84 coordinates
* @param wp The point to convert to into the local coordinates, in WGS84 coordinates
* @return The vector in meters pointing from the reference position to the coordinates
*/
math::Vector<2> get_local_planar_vector(const math::Vector<2> &origin, const math::Vector<2> &target) const;
};
#endif /* ECL_L1_POS_CONTROLLER_H */