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/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
# include <AP_HAL.h>
# include <AC_Circle.h>
extern const AP_HAL : : HAL & hal ;
const AP_Param : : GroupInfo AC_Circle : : var_info [ ] PROGMEM = {
// @Param: RADIUS
// @DisplayName: Circle Radius
// @Description: Defines the radius of the circle the vehicle will fly when in Circle flight mode
// @Units: cm
// @Range: 0 10000
// @Increment: 100
// @User: Standard
AP_GROUPINFO ( " RADIUS " , 0 , AC_Circle , _radius , AC_CIRCLE_RADIUS_DEFAULT ) ,
// @Param: RATE
// @DisplayName: Circle rate
// @Description: Circle mode's turn rate in deg/sec. Positive to turn clockwise, negative for counter clockwise
// @Units: deg/s
// @Range: -90 90
// @Increment: 1
// @User: Standard
AP_GROUPINFO ( " RATE " , 1 , AC_Circle , _rate , AC_CIRCLE_RATE_DEFAULT ) ,
AP_GROUPEND
} ;
// Default constructor.
// Note that the Vector/Matrix constructors already implicitly zero
// their values.
//
AC_Circle : : AC_Circle ( const AP_InertialNav & inav , const AP_AHRS & ahrs , AC_PosControl & pos_control ) :
_inav ( inav ) ,
_ahrs ( ahrs ) ,
_pos_control ( pos_control ) ,
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_yaw ( 0.0f ) ,
_angle ( 0.0f ) ,
_angle_total ( 0.0f ) ,
_angular_vel ( 0.0f ) ,
_angular_vel_max ( 0.0f ) ,
_angular_accel ( 0.0f )
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{
AP_Param : : setup_object_defaults ( this , var_info ) ;
}
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/// init - initialise circle controller setting center specifically
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/// caller should set the position controller's x,y and z speeds and accelerations before calling this
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void AC_Circle : : init ( const Vector3f & center )
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{
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_center = center ;
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// initialise position controller (sets target roll angle, pitch angle and I terms based on vehicle current lean angles)
_pos_control . init_xy_controller ( ) ;
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// set initial position target to reasonable stopping point
_pos_control . set_target_to_stopping_point_xy ( ) ;
_pos_control . set_target_to_stopping_point_z ( ) ;
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// calculate velocities
calc_velocities ( ) ;
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// set start angle from position
init_start_angle ( false ) ;
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}
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/// init - initialise circle controller setting center using stopping point and projecting out based on the copter's heading
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/// caller should set the position controller's x,y and z speeds and accelerations before calling this
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void AC_Circle : : init ( )
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{
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// initialise position controller (sets target roll angle, pitch angle and I terms based on vehicle current lean angles)
_pos_control . init_xy_controller ( ) ;
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// set initial position target to reasonable stopping point
_pos_control . set_target_to_stopping_point_xy ( ) ;
_pos_control . set_target_to_stopping_point_z ( ) ;
// get stopping point
const Vector3f & stopping_point = _pos_control . get_pos_target ( ) ;
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// set circle center to circle_radius ahead of stopping point
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_center . x = stopping_point . x + _radius * _ahrs . cos_yaw ( ) ;
_center . y = stopping_point . y + _radius * _ahrs . sin_yaw ( ) ;
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_center . z = stopping_point . z ;
// calculate velocities
calc_velocities ( ) ;
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// set starting angle from vehicle heading
init_start_angle ( true ) ;
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}
/// update - update circle controller
void AC_Circle : : update ( )
{
// calculate dt
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float dt = _pos_control . time_since_last_xy_update ( ) ;
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// update circle position at poscontrol update rate
if ( dt > = _pos_control . get_dt_xy ( ) ) {
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// double check dt is reasonable
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if ( dt > = 0.2f ) {
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dt = 0.0 ;
}
// ramp up angular velocity to maximum
if ( _rate > = 0 ) {
if ( _angular_vel < _angular_vel_max ) {
_angular_vel + = _angular_accel * dt ;
_angular_vel = constrain_float ( _angular_vel , 0 , _angular_vel_max ) ;
}
} else {
if ( _angular_vel > _angular_vel_max ) {
_angular_vel + = _angular_accel * dt ;
_angular_vel = constrain_float ( _angular_vel , _angular_vel_max , 0 ) ;
}
}
// update the target angle and total angle traveled
float angle_change = _angular_vel * dt ;
_angle + = angle_change ;
_angle = wrap_PI ( _angle ) ;
_angle_total + = angle_change ;
// if the circle_radius is zero we are doing panorama so no need to update loiter target
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if ( _radius ! = 0.0f ) {
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// calculate target position
Vector3f target ;
target . x = _center . x + _radius * cosf ( - _angle ) ;
target . y = _center . y - _radius * sinf ( - _angle ) ;
target . z = _pos_control . get_alt_target ( ) ;
// update position controller target
_pos_control . set_pos_target ( target ) ;
// heading is 180 deg from vehicles target position around circle
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_yaw = wrap_PI ( _angle - PI ) * AC_CIRCLE_DEGX100 ;
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} else {
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// set target position to center
Vector3f target ;
target . x = _center . x ;
target . y = _center . y ;
target . z = _pos_control . get_alt_target ( ) ;
// update position controller target
_pos_control . set_pos_target ( target ) ;
// heading is same as _angle but converted to centi-degrees
_yaw = _angle * AC_CIRCLE_DEGX100 ;
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}
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// update position controller
_pos_control . update_xy_controller ( false , 1.0f ) ;
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}
}
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// get_closest_point_on_circle - returns closest point on the circle
// circle's center should already have been set
// closest point on the circle will be placed in result
// result's altitude (i.e. z) will be set to the circle_center's altitude
// if vehicle is at the center of the circle, the edge directly behind vehicle will be returned
void AC_Circle : : get_closest_point_on_circle ( Vector3f & result )
{
// return center if radius is zero
if ( _radius < = 0 ) {
result = _center ;
return ;
}
// get current position
const Vector3f & curr_pos = _inav . get_position ( ) ;
// calc vector from current location to circle center
Vector2f vec ; // vector from circle center to current location
vec . x = ( curr_pos . x - _center . x ) ;
vec . y = ( curr_pos . y - _center . y ) ;
float dist = pythagorous2 ( vec . x , vec . y ) ;
// if current location is exactly at the center of the circle return edge directly behind vehicle
if ( dist = = 0 ) {
result . x = _center . x - _radius * _ahrs . cos_yaw ( ) ;
result . y = _center . y - _radius * _ahrs . sin_yaw ( ) ;
result . z = _center . z ;
return ;
}
// calculate closest point on edge of circle
result . x = _center . x + vec . x / dist * _radius ;
result . y = _center . y + vec . y / dist * _radius ;
result . z = _center . z ;
}
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// calc_velocities - calculate angular velocity max and acceleration based on radius and rate
// this should be called whenever the radius or rate are changed
// initialises the yaw and current position around the circle
void AC_Circle : : calc_velocities ( )
{
// if we are doing a panorama set the circle_angle to the current heading
if ( _radius < = 0 ) {
_angular_vel_max = ToRad ( _rate ) ;
_angular_accel = _angular_vel_max ; // reach maximum yaw velocity in 1 second
} else {
// set starting angle to current heading - 180 degrees
_angle = wrap_PI ( _ahrs . yaw - PI ) ;
// calculate max velocity based on waypoint speed ensuring we do not use more than half our max acceleration for accelerating towards the center of the circle
float velocity_max = min ( _pos_control . get_speed_xy ( ) , safe_sqrt ( 0.5f * _pos_control . get_accel_xy ( ) * _radius ) ) ;
// angular_velocity in radians per second
_angular_vel_max = velocity_max / _radius ;
_angular_vel_max = constrain_float ( ToRad ( _rate ) , - _angular_vel_max , _angular_vel_max ) ;
// angular_velocity in radians per second
_angular_accel = _pos_control . get_accel_xy ( ) / _radius ;
if ( _rate < 0.0f ) {
_angular_accel = - _angular_accel ;
}
}
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// initialise angular velocity
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_angular_vel = 0 ;
}
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// init_start_angle - sets the starting angle around the circle and initialises the angle_total
// if use_heading is true the vehicle's heading will be used to init the angle causing minimum yaw movement
// if use_heading is false the vehicle's position from the center will be used to initialise the angle
void AC_Circle : : init_start_angle ( bool use_heading )
{
// initialise angle total
_angle_total = 0 ;
// if the radius is zero we are doing panorama so init angle to the current heading
if ( _radius < = 0 ) {
_angle = _ahrs . yaw ;
return ;
}
// if use_heading is true
if ( use_heading ) {
_angle = wrap_PI ( _ahrs . yaw - PI ) ;
} else {
// if we are exactly at the center of the circle, init angle to directly behind vehicle (so vehicle will backup but not change heading)
const Vector3f & curr_pos = _inav . get_position ( ) ;
if ( curr_pos . x = = _center . x & & curr_pos . y = = _center . y ) {
_angle = wrap_PI ( _ahrs . yaw - PI ) ;
} else {
// get bearing from circle center to vehicle in radians
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float bearing_rad = ToRad ( 90 ) + fast_atan2 ( - ( curr_pos . x - _center . x ) , curr_pos . y - _center . y ) ;
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_angle = wrap_PI ( bearing_rad ) ;
}
}
}