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/*
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 < http : //www.gnu.org/licenses/>.
*/
# include <AP_Math/AP_Math.h>
# include <AP_HAL/AP_HAL.h>
# include "AR_WPNav.h"
extern const AP_HAL : : HAL & hal ;
# define AR_WPNAV_TIMEOUT_MS 100
# define AR_WPNAV_SPEED_DEFAULT 2.0f
# define AR_WPNAV_RADIUS_DEFAULT 2.0f
# define AR_WPNAV_OVERSHOOT_DEFAULT 2.0f
# define AR_WPNAV_PIVOT_ANGLE_DEFAULT 60
# define AR_WPNAV_PIVOT_RATE_DEFAULT 90
const AP_Param : : GroupInfo AR_WPNav : : var_info [ ] = {
// @Param: SPEED
// @DisplayName: Waypoint speed default
// @Description: Waypoint speed default
// @Units: m/s
// @Range: 0 100
// @Increment: 0.1
// @User: Standard
AP_GROUPINFO ( " SPEED " , 1 , AR_WPNav , _speed_max , AR_WPNAV_SPEED_DEFAULT ) ,
// @Param: RADIUS
// @DisplayName: Waypoint radius
// @Description: The distance in meters from a waypoint when we consider the waypoint has been reached. This determines when the vehicle will turn toward the next waypoint.
// @Units: m
// @Range: 0 100
// @Increment: 0.1
// @User: Standard
AP_GROUPINFO ( " RADIUS " , 2 , AR_WPNav , _radius , AR_WPNAV_RADIUS_DEFAULT ) ,
// @Param: OVERSHOOT
// @DisplayName: Waypoint overshoot maximum
// @Description: Waypoint overshoot maximum in meters. The vehicle will attempt to stay within this many meters of the track as it completes one waypoint and moves to the next.
// @Units: m
// @Range: 0 10
// @Increment: 0.1
// @User: Standard
AP_GROUPINFO ( " OVERSHOOT " , 3 , AR_WPNav , _overshoot , AR_WPNAV_OVERSHOOT_DEFAULT ) ,
// @Param: PIVOT_ANGLE
// @DisplayName: Waypoint Pivot Angle
// @Description: Pivot when the difference bewteen the vehicle's heading and it's target heading is more than this many degrees. Set to zero to disable pivot turns
// @Units: deg
// @Range: 0 360
// @Increment: 1
// @User: Standard
AP_GROUPINFO ( " PIVOT_ANGLE " , 4 , AR_WPNav , _pivot_angle , AR_WPNAV_PIVOT_ANGLE_DEFAULT ) ,
// @Param: PIVOT_RATE
// @DisplayName: Waypoint Pivot Turn Rate
// @Description: Turn rate during pivot turns
// @Units: deg/s
// @Range: 0 360
// @Increment: 1
// @User: Standard
AP_GROUPINFO ( " PIVOT_RATE " , 5 , AR_WPNav , _pivot_rate , AR_WPNAV_PIVOT_RATE_DEFAULT ) ,
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// @Param: SPEED_MIN
// @DisplayName: Waypoint speed minimum
// @Description: Vehicle will not slow below this speed for corners. Should be set to boat's plane speed. Does not apply to pivot turns.
// @Units: m/s
// @Range: 0 100
// @Increment: 0.1
// @User: Standard
AP_GROUPINFO ( " SPEED_MIN " , 6 , AR_WPNav , _speed_min , 0 ) ,
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AP_GROUPEND
} ;
AR_WPNav : : AR_WPNav ( AR_AttitudeControl & atc , AP_Navigation & nav_controller ) :
_atc ( atc ) ,
_nav_controller ( nav_controller )
{
AP_Param : : setup_object_defaults ( this , var_info ) ;
}
// update navigation
void AR_WPNav : : update ( float dt )
{
// exit immediately if no current location, origin or destination
Location current_loc ;
float speed ;
if ( ! hal . util - > get_soft_armed ( ) | | ! _orig_and_dest_valid | | ! AP : : ahrs ( ) . get_position ( current_loc ) | | ! _atc . get_forward_speed ( speed ) ) {
_desired_speed_limited = _atc . get_desired_speed_accel_limited ( 0.0f , dt ) ;
_desired_turn_rate_rads = 0.0f ;
return ;
}
// if no recent calls initialise desired_speed_limited to current speed
if ( ! is_active ( ) ) {
_desired_speed_limited = speed ;
}
_last_update_ms = AP_HAL : : millis ( ) ;
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// run path planning around obstacles
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bool stop_vehicle = false ;
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AP_OAPathPlanner * oa = AP_OAPathPlanner : : get_singleton ( ) ;
if ( oa ! = nullptr ) {
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const AP_OAPathPlanner : : OA_RetState oa_retstate = oa - > mission_avoidance ( current_loc , _origin , _destination , _oa_origin , _oa_destination ) ;
switch ( oa_retstate ) {
case AP_OAPathPlanner : : OA_NOT_REQUIRED :
_oa_active = false ;
break ;
case AP_OAPathPlanner : : OA_PROCESSING :
case AP_OAPathPlanner : : OA_ERROR :
// during processing or in case of error, slow vehicle to a stop
stop_vehicle = true ;
_oa_active = false ;
break ;
case AP_OAPathPlanner : : OA_SUCCESS :
_oa_active = true ;
break ;
}
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}
if ( ! _oa_active ) {
_oa_origin = _origin ;
_oa_destination = _destination ;
}
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update_distance_and_bearing_to_destination ( ) ;
// check if vehicle has reached the destination
const bool near_wp = _distance_to_destination < = _radius ;
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const bool past_wp = ! _oa_active & & current_loc . past_interval_finish_line ( _origin , _destination ) ;
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if ( ! _reached_destination & & ( near_wp | | past_wp ) ) {
_reached_destination = true ;
}
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// handle stopping vehicle if avoidance has failed
if ( stop_vehicle ) {
// decelerate to speed to zero and set turn rate to zero
_desired_speed_limited = _atc . get_desired_speed_accel_limited ( 0.0f , dt ) ;
_desired_lat_accel = 0.0f ;
_desired_turn_rate_rads = 0.0f ;
return ;
}
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// calculate the required turn of the wheels
update_steering ( current_loc , speed ) ;
// calculate desired speed
update_desired_speed ( dt ) ;
}
// set desired location
bool AR_WPNav : : set_desired_location ( const struct Location & destination , float next_leg_bearing_cd )
{
// set origin to last destination if waypoint controller active
if ( is_active ( ) & & _orig_and_dest_valid & & _reached_destination ) {
_origin = _destination ;
} else {
// otherwise use reasonable stopping point
if ( ! get_stopping_location ( _origin ) ) {
return false ;
}
}
// initialise some variables
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_oa_origin = _origin ;
_oa_destination = _destination = destination ;
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_orig_and_dest_valid = true ;
_reached_destination = false ;
update_distance_and_bearing_to_destination ( ) ;
// set final desired speed
_desired_speed_final = 0.0f ;
if ( ! is_equal ( next_leg_bearing_cd , AR_WPNAV_HEADING_UNKNOWN ) ) {
const float curr_leg_bearing_cd = _origin . get_bearing_to ( _destination ) ;
const float turn_angle_cd = wrap_180_cd ( next_leg_bearing_cd - curr_leg_bearing_cd ) ;
if ( fabsf ( turn_angle_cd ) < 10.0f ) {
// if turning less than 0.1 degrees vehicle can continue at full speed
// we use 0.1 degrees instead of zero to avoid divide by zero in calcs below
_desired_speed_final = _desired_speed ;
} else if ( use_pivot_steering_at_next_WP ( turn_angle_cd ) ) {
// pivoting so we will stop
_desired_speed_final = 0.0f ;
} else {
// calculate maximum speed that keeps overshoot within bounds
const float radius_m = fabsf ( _overshoot / ( cosf ( radians ( turn_angle_cd * 0.01f ) ) - 1.0f ) ) ;
_desired_speed_final = MIN ( _desired_speed , safe_sqrt ( _turn_max_mss * radius_m ) ) ;
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// ensure speed does not fall below minimum
apply_speed_min ( _desired_speed_final ) ;
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}
}
return true ;
}
// set desired location to a reasonable stopping point, return true on success
bool AR_WPNav : : set_desired_location_to_stopping_location ( )
{
Location stopping_loc ;
if ( ! get_stopping_location ( stopping_loc ) ) {
return false ;
}
return set_desired_location ( stopping_loc ) ;
}
// set desired location as offset from the EKF origin, return true on success
bool AR_WPNav : : set_desired_location_NED ( const Vector3f & destination , float next_leg_bearing_cd )
{
// initialise destination to ekf origin
Location destination_ned ;
if ( ! AP : : ahrs ( ) . get_origin ( destination_ned ) ) {
return false ;
}
// apply offset
destination_ned . offset ( destination . x , destination . y ) ;
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return set_desired_location ( destination_ned , next_leg_bearing_cd ) ;
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}
// calculate vehicle stopping point using current location, velocity and maximum acceleration
bool AR_WPNav : : get_stopping_location ( Location & stopping_loc )
{
Location current_loc ;
if ( ! AP : : ahrs ( ) . get_position ( current_loc ) ) {
return false ;
}
// get current velocity vector and speed
const Vector2f velocity = AP : : ahrs ( ) . groundspeed_vector ( ) ;
const float speed = velocity . length ( ) ;
// avoid divide by zero
if ( ! is_positive ( speed ) ) {
stopping_loc = current_loc ;
return true ;
}
// get stopping distance in meters
const float stopping_dist = _atc . get_stopping_distance ( speed ) ;
// calculate stopping position from current location in meters
const Vector2f stopping_offset = velocity . normalized ( ) * stopping_dist ;
stopping_loc = current_loc ;
stopping_loc . offset ( stopping_offset . x , stopping_offset . y ) ;
return true ;
}
// returns true if vehicle should pivot turn at next waypoint
bool AR_WPNav : : use_pivot_steering_at_next_WP ( float yaw_error_cd ) const
{
// check cases where we clearly cannot use pivot steering
if ( ! _pivot_possible | | _pivot_angle < = 0 ) {
return false ;
}
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// if error is larger than _pivot_angle then use pivot steering at next WP
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if ( fabsf ( yaw_error_cd ) * 0.01f > _pivot_angle ) {
return true ;
}
return false ;
}
// returns true if vehicle should pivot immediately (because heading error is too large)
bool AR_WPNav : : use_pivot_steering ( float yaw_error_cd )
{
// check cases where we clearly cannot use pivot steering
if ( ! _pivot_possible | | ( _pivot_angle < = 0 ) ) {
_pivot_active = false ;
return false ;
}
// calc bearing error
const float yaw_error = fabsf ( yaw_error_cd ) * 0.01f ;
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// if error is larger than _pivot_angle start pivot steering
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if ( yaw_error > _pivot_angle ) {
_pivot_active = true ;
return true ;
}
// if within 10 degrees of the target heading, exit pivot steering
if ( yaw_error < 10.0f ) {
_pivot_active = false ;
return false ;
}
// by default stay in
return _pivot_active ;
}
// true if update has been called recently
bool AR_WPNav : : is_active ( ) const
{
return ( ( AP_HAL : : millis ( ) - _last_update_ms ) < AR_WPNAV_TIMEOUT_MS ) ;
}
// update distance from vehicle's current position to destination
void AR_WPNav : : update_distance_and_bearing_to_destination ( )
{
// if no current location leave distance unchanged
Location current_loc ;
if ( ! _orig_and_dest_valid | | ! AP : : ahrs ( ) . get_position ( current_loc ) ) {
_distance_to_destination = 0.0f ;
_wp_bearing_cd = 0.0f ;
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// update OA adjusted values
_oa_distance_to_destination = 0.0f ;
_oa_wp_bearing_cd = 0.0f ;
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return ;
}
_distance_to_destination = current_loc . get_distance ( _destination ) ;
_wp_bearing_cd = current_loc . get_bearing_to ( _destination ) ;
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// update OA adjusted values
if ( _oa_active ) {
_oa_distance_to_destination = current_loc . get_distance ( _oa_destination ) ;
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_oa_wp_bearing_cd = current_loc . get_bearing_to ( _oa_destination ) ;
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} else {
_oa_distance_to_destination = _distance_to_destination ;
_oa_wp_bearing_cd = _wp_bearing_cd ;
}
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}
// calculate steering output to drive along line from origin to destination waypoint
// relies on update_distance_and_bearing_to_destination being called first so _wp_bearing_cd has been updated
void AR_WPNav : : update_steering ( const Location & current_loc , float current_speed )
{
// calculate yaw error for determining if vehicle should pivot towards waypoint
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float yaw_cd = _reversed ? wrap_360_cd ( _oa_wp_bearing_cd + 18000 ) : _oa_wp_bearing_cd ;
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float yaw_error_cd = wrap_180_cd ( yaw_cd - AP : : ahrs ( ) . yaw_sensor ) ;
// calculate desired turn rate and update desired heading
if ( use_pivot_steering ( yaw_error_cd ) ) {
_cross_track_error = 0.0f ;
_desired_heading_cd = yaw_cd ;
_desired_lat_accel = 0.0f ;
_desired_turn_rate_rads = _atc . get_turn_rate_from_heading ( radians ( yaw_cd * 0.01f ) , radians ( _pivot_rate ) ) ;
} else {
// run L1 controller
_nav_controller . set_reverse ( _reversed ) ;
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_nav_controller . update_waypoint ( _reached_destination ? current_loc : _oa_origin , _oa_destination , _radius ) ;
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// retrieve lateral acceleration, heading back towards line and crosstrack error
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_desired_lat_accel = constrain_float ( _nav_controller . lateral_acceleration ( ) , - _turn_max_mss , _turn_max_mss ) ;
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_desired_heading_cd = wrap_360_cd ( _nav_controller . nav_bearing_cd ( ) ) ;
if ( _reversed ) {
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_desired_lat_accel * = - 1.0f ;
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_desired_heading_cd = wrap_360_cd ( _desired_heading_cd + 18000 ) ;
}
_cross_track_error = _nav_controller . crosstrack_error ( ) ;
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_desired_turn_rate_rads = _atc . get_turn_rate_from_lat_accel ( _desired_lat_accel , current_speed ) ;
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}
}
// calculated desired speed(in m/s) based on yaw error and lateral acceleration and/or distance to a waypoint
// relies on update_distance_and_bearing_to_destination and update_steering being run so these internal members
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// have been updated: _oa_wp_bearing_cd, _cross_track_error, _oa_distance_to_destination
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void AR_WPNav : : update_desired_speed ( float dt )
{
// reduce speed to zero during pivot turns
if ( _pivot_active ) {
// decelerate to zero
_desired_speed_limited = _atc . get_desired_speed_accel_limited ( 0.0f , dt ) ;
return ;
}
// accelerate desired speed towards max
float des_speed_lim = _atc . get_desired_speed_accel_limited ( _reversed ? - _desired_speed : _desired_speed , dt ) ;
// reduce speed to limit overshoot from line between origin and destination
// calculate number of degrees vehicle must turn to face waypoint
float ahrs_yaw_sensor = AP : : ahrs ( ) . yaw_sensor ;
const float heading_cd = is_negative ( des_speed_lim ) ? wrap_180_cd ( ahrs_yaw_sensor + 18000 ) : ahrs_yaw_sensor ;
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const float wp_yaw_diff_cd = wrap_180_cd ( _oa_wp_bearing_cd - heading_cd ) ;
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const float turn_angle_rad = fabsf ( radians ( wp_yaw_diff_cd * 0.01f ) ) ;
// calculate distance from vehicle to line + wp_overshoot
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const float line_yaw_diff = wrap_180_cd ( _oa_origin . get_bearing_to ( _oa_destination ) - heading_cd ) ;
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const float dist_from_line = fabsf ( _cross_track_error ) ;
const bool heading_away = is_positive ( line_yaw_diff ) = = is_positive ( _cross_track_error ) ;
const float wp_overshoot_adj = heading_away ? - dist_from_line : dist_from_line ;
// calculate radius of circle that touches vehicle's current position and heading and target position and heading
float radius_m = 999.0f ;
const float radius_calc_denom = fabsf ( 1.0f - cosf ( turn_angle_rad ) ) ;
if ( ! is_zero ( radius_calc_denom ) ) {
radius_m = MAX ( 0.0f , _overshoot + wp_overshoot_adj ) / radius_calc_denom ;
}
// calculate and limit speed to allow vehicle to stay on circle
const float overshoot_speed_max = safe_sqrt ( _turn_max_mss * MAX ( _turn_radius , radius_m ) ) ;
des_speed_lim = constrain_float ( des_speed_lim , - overshoot_speed_max , overshoot_speed_max ) ;
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// ensure speed does not fall below minimum
apply_speed_min ( des_speed_lim ) ;
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// limit speed based on distance to waypoint and max acceleration/deceleration
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if ( is_positive ( _oa_distance_to_destination ) & & is_positive ( _atc . get_decel_max ( ) ) ) {
const float dist_speed_max = safe_sqrt ( 2.0f * _oa_distance_to_destination * _atc . get_decel_max ( ) + sq ( _desired_speed_final ) ) ;
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des_speed_lim = constrain_float ( des_speed_lim , - dist_speed_max , dist_speed_max ) ;
}
_desired_speed_limited = des_speed_lim ;
}
// settor to allow vehicle code to provide turn related param values to this library (should be updated regularly)
void AR_WPNav : : set_turn_params ( float turn_max_g , float turn_radius , bool pivot_possible )
{
_turn_max_mss = turn_max_g * GRAVITY_MSS ;
_turn_radius = turn_radius ;
_pivot_possible = pivot_possible ;
}
// set default overshoot (used for sailboats)
void AR_WPNav : : set_default_overshoot ( float overshoot )
{
_overshoot . set_default ( overshoot ) ;
}
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// adjust speed to ensure it does not fall below value held in SPEED_MIN
void AR_WPNav : : apply_speed_min ( float & desired_speed )
{
if ( ! is_positive ( _speed_min ) ) {
return ;
}
float speed_min = MIN ( _speed_min , _speed_max ) ;
// ensure speed does not fall below minimum
if ( fabsf ( desired_speed ) < speed_min ) {
desired_speed = is_negative ( desired_speed ) ? - speed_min : speed_min ;
}
}