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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_AttitudeControl.h"
extern const AP_HAL : : HAL & hal ;
const AP_Param : : GroupInfo AR_AttitudeControl : : var_info [ ] = {
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// @Param: _STR_RAT_P
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// @DisplayName: Steering control rate P gain
// @Description: Steering control rate P gain. Converts the turn rate error (in radians/sec) to a steering control output (in the range -1 to +1)
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// @Range: 0.000 2.000
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// @Increment: 0.01
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// @User: Standard
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// @Param: _STR_RAT_I
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// @DisplayName: Steering control I gain
// @Description: Steering control I gain. Corrects long term error between the desired turn rate (in rad/s) and actual
// @Range: 0.000 2.000
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// @Increment: 0.01
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// @User: Standard
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// @Param: _STR_RAT_IMAX
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// @DisplayName: Steering control I gain maximum
// @Description: Steering control I gain maximum. Constraings the steering output (range -1 to +1) that the I term will generate
// @Range: 0.000 1.000
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// @Increment: 0.01
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// @User: Standard
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// @Param: _STR_RAT_D
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// @DisplayName: Steering control D gain
// @Description: Steering control D gain. Compensates for short-term change in desired turn rate vs actual
// @Range: 0.000 0.400
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// @Increment: 0.001
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// @User: Standard
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// @Param: _STR_RAT_FF
// @DisplayName: Steering control feed forward
// @Description: Steering control feed forward
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// @Range: 0.000 3.000
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// @Increment: 0.001
// @User: Standard
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// @Param: _STR_RAT_FILT
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// @DisplayName: Steering control filter frequency
// @Description: Steering control input filter. Lower values reduce noise but add delay.
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// @Range: 0.000 100.000
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// @Increment: 0.1
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// @Units: Hz
// @User: Standard
AP_SUBGROUPINFO ( _steer_rate_pid , " _STR_RAT_ " , 1 , AR_AttitudeControl , AC_PID ) ,
// @Param: _SPEED_P
// @DisplayName: Speed control P gain
// @Description: Speed control P gain. Converts the error between the desired speed (in m/s) and actual speed to a motor output (in the range -1 to +1)
// @Range: 0.010 2.000
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// @Increment: 0.01
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// @User: Standard
// @Param: _SPEED_I
// @DisplayName: Speed control I gain
// @Description: Speed control I gain. Corrects long term error between the desired speed (in m/s) and actual speed
// @Range: 0.000 2.000
// @User: Standard
// @Param: _SPEED_IMAX
// @DisplayName: Speed control I gain maximum
// @Description: Speed control I gain maximum. Constraings the maximum motor output (range -1 to +1) that the I term will generate
// @Range: 0.000 1.000
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// @Increment: 0.01
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// @User: Standard
// @Param: _SPEED_D
// @DisplayName: Speed control D gain
// @Description: Speed control D gain. Compensates for short-term change in desired speed vs actual
// @Range: 0.000 0.400
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// @Increment: 0.001
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// @User: Standard
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// @Param: _SPEED_FF
// @DisplayName: Speed control feed forward
// @Description: Speed control feed forward
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// @Range: 0.000 0.500
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// @Increment: 0.001
// @User: Standard
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// @Param: _SPEED_FILT
// @DisplayName: Speed control filter frequency
// @Description: Speed control input filter. Lower values reduce noise but add delay.
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// @Range: 0.000 100.000
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// @Increment: 0.1
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// @Units: Hz
// @User: Standard
AP_SUBGROUPINFO ( _throttle_speed_pid , " _SPEED_ " , 2 , AR_AttitudeControl , AC_PID ) ,
// @Param: _ACCEL_MAX
// @DisplayName: Speed control acceleration (and deceleration) maximum in m/s/s
// @Description: Speed control acceleration (and deceleration) maximum in m/s/s. 0 to disable acceleration limiting
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// @Range: 0.0 10.0
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// @Increment: 0.1
// @Units: m/s/s
// @User: Standard
AP_GROUPINFO ( " _ACCEL_MAX " , 3 , AR_AttitudeControl , _throttle_accel_max , AR_ATTCONTROL_THR_ACCEL_MAX ) ,
// @Param: _BRAKE
// @DisplayName: Speed control brake enable/disable
// @Description: Speed control brake enable/disable. Allows sending a reversed output to the motors to slow the vehicle.
// @Values: 0:Disable,1:Enable
// @User: Standard
AP_GROUPINFO ( " _BRAKE " , 4 , AR_AttitudeControl , _brake_enable , 0 ) ,
// @Param: _STOP_SPEED
// @DisplayName: Speed control stop speed
// @Description: Speed control stop speed. Motor outputs to zero once vehicle speed falls below this value
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// @Range: 0.00 0.50
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// @Increment: 0.01
// @Units: m/s
// @User: Standard
AP_GROUPINFO ( " _STOP_SPEED " , 5 , AR_AttitudeControl , _stop_speed , AR_ATTCONTROL_STOP_SPEED_DEFAULT ) ,
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// @Param: _STR_ANG_P
// @DisplayName: Steering control angle P gain
// @Description: Steering control angle P gain. Converts the error between the desired heading/yaw (in radians) and actual heading/yaw to a desired turn rate (in rad/sec)
// @Range: 1.000 10.000
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// @Increment: 0.1
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// @User: Standard
AP_SUBGROUPINFO ( _steer_angle_p , " _STR_ANG_ " , 6 , AR_AttitudeControl , AC_P ) ,
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AP_GROUPEND
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} ;
AR_AttitudeControl : : AR_AttitudeControl ( AP_AHRS & ahrs ) :
_ahrs ( ahrs ) ,
_steer_angle_p ( AR_ATTCONTROL_STEER_ANG_P ) ,
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_steer_rate_pid ( AR_ATTCONTROL_STEER_RATE_P , AR_ATTCONTROL_STEER_RATE_I , AR_ATTCONTROL_STEER_RATE_D , AR_ATTCONTROL_STEER_RATE_IMAX , AR_ATTCONTROL_STEER_RATE_FILT , AR_ATTCONTROL_DT , AR_ATTCONTROL_STEER_RATE_FF ) ,
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_throttle_speed_pid ( AR_ATTCONTROL_THR_SPEED_P , AR_ATTCONTROL_THR_SPEED_I , AR_ATTCONTROL_THR_SPEED_D , AR_ATTCONTROL_THR_SPEED_IMAX , AR_ATTCONTROL_THR_SPEED_FILT , AR_ATTCONTROL_DT )
{
AP_Param : : setup_object_defaults ( this , var_info ) ;
}
// return a steering servo output from -1.0 to +1.0 given a desired lateral acceleration rate in m/s/s.
// positive lateral acceleration is to the right.
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float AR_AttitudeControl : : get_steering_out_lat_accel ( float desired_accel , bool skid_steering , bool motor_limit_left , bool motor_limit_right , bool reversed )
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{
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// record desired accel for reporting purposes
_steer_lat_accel_last_ms = AP_HAL : : millis ( ) ;
_desired_lat_accel = desired_accel ;
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// get speed forward
float speed ;
if ( ! get_forward_speed ( speed ) ) {
// we expect caller will not try to control heading using rate control without a valid speed estimate
// on failure to get speed we do not attempt to steer
return 0.0f ;
}
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// only use positive speed. Use reverse flag instead of negative speeds.
speed = fabsf ( speed ) ;
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// enforce minimum speed to stop oscillations when first starting to move
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if ( speed < AR_ATTCONTROL_STEER_SPEED_MIN ) {
speed = AR_ATTCONTROL_STEER_SPEED_MIN ;
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}
// Calculate the desired steering rate given desired_accel and speed
float desired_rate = desired_accel / speed ;
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// invert rate if we are going backwards
if ( reversed ) {
desired_rate * = - 1.0f ;
}
return get_steering_out_rate ( desired_rate , skid_steering , motor_limit_left , motor_limit_right , reversed ) ;
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}
// return a steering servo output from -1 to +1 given a yaw error in radians
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float AR_AttitudeControl : : get_steering_out_angle_error ( float angle_err , bool skid_steering , bool motor_limit_left , bool motor_limit_right , bool reversed )
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{
// Calculate the desired turn rate (in radians) from the angle error (also in radians)
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const float desired_rate = _steer_angle_p . get_p ( angle_err ) ;
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return get_steering_out_rate ( desired_rate , skid_steering , motor_limit_left , motor_limit_right , reversed ) ;
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}
// return a steering servo output from -1 to +1 given a
// desired yaw rate in radians/sec. Positive yaw is to the right.
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float AR_AttitudeControl : : get_steering_out_rate ( float desired_rate , bool skid_steering , bool motor_limit_left , bool motor_limit_right , bool reversed )
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{
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// record desired turn rate for reporting purposes
_desired_turn_rate = desired_rate ;
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// calculate dt
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const uint32_t now = AP_HAL : : millis ( ) ;
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float dt = ( now - _steer_turn_last_ms ) / 1000.0f ;
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if ( ( _steer_turn_last_ms = = 0 ) | | ( dt > ( AR_ATTCONTROL_TIMEOUT_MS / 1000.0f ) ) ) {
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dt = 0.0f ;
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_steer_rate_pid . reset_filter ( ) ;
} else {
_steer_rate_pid . set_dt ( dt ) ;
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}
_steer_turn_last_ms = now ;
// get speed forward
float speed ;
if ( ! get_forward_speed ( speed ) ) {
// we expect caller will not try to control heading using rate control without a valid speed estimate
// on failure to get speed we do not attempt to steer
return 0.0f ;
}
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// only use positive speed. Use reverse flag instead of negative speeds.
speed = fabsf ( speed ) ;
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// enforce minimum speed to stop oscillations when first starting to move
bool low_speed = false ;
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if ( speed < AR_ATTCONTROL_STEER_SPEED_MIN ) {
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low_speed = true ;
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speed = AR_ATTCONTROL_STEER_SPEED_MIN ;
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}
// scaler to linearize output because turn rate increases as vehicle speed increases on non-skid steering vehicles
float scaler = 1.0f ;
if ( ! skid_steering ) {
scaler = 1.0f / fabsf ( speed ) ;
}
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// Calculate the steering rate error (rad/sec) and apply gain scaler
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// We do this in earth frame to allow for rover leaning over in hard corners
float yaw_rate_earth = _ahrs . get_yaw_rate_earth ( ) ;
// check if reversing
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if ( reversed ) {
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yaw_rate_earth * = - 1.0f ;
}
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const float rate_error = ( desired_rate - yaw_rate_earth ) * scaler ;
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// record desired rate for logging purposes only
_steer_rate_pid . set_desired_rate ( desired_rate ) ;
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// pass error to PID controller
_steer_rate_pid . set_input_filter_all ( rate_error ) ;
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// get feed-forward
const float ff = _steer_rate_pid . get_ff ( desired_rate * scaler ) ;
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// get p
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const float p = _steer_rate_pid . get_p ( ) ;
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// get i unless non-skid-steering rover at low speed or steering output has hit a limit
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float i = _steer_rate_pid . get_integrator ( ) ;
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if ( ( ! low_speed | | skid_steering ) & & ( ( is_negative ( rate_error ) & & ! motor_limit_left ) | | ( is_positive ( rate_error ) & & ! motor_limit_right ) ) ) {
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i = _steer_rate_pid . get_i ( ) ;
}
// get d
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const float d = _steer_rate_pid . get_d ( ) ;
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// constrain and return final output
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return constrain_float ( ff + p + i + d , - 1.0f , 1.0f ) ;
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}
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// get latest desired turn rate in rad/sec (recorded during calls to get_steering_out_rate)
float AR_AttitudeControl : : get_desired_turn_rate ( ) const
{
// return zero if no recent calls to turn rate controller
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if ( ( _steer_turn_last_ms = = 0 ) | | ( ( AP_HAL : : millis ( ) - _steer_turn_last_ms ) > AR_ATTCONTROL_TIMEOUT_MS ) ) {
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return 0.0f ;
}
return _desired_turn_rate ;
}
// get latest desired lateral acceleration in m/s/s (recorded during calls to get_steering_out_lat_accel)
float AR_AttitudeControl : : get_desired_lat_accel ( ) const
{
// return zero if no recent calls to lateral acceleration controller
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if ( ( _steer_lat_accel_last_ms = = 0 ) | | ( ( AP_HAL : : millis ( ) - _steer_lat_accel_last_ms ) > AR_ATTCONTROL_TIMEOUT_MS ) ) {
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return 0.0f ;
}
return _desired_lat_accel ;
}
// get actual lateral acceleration in m/s/s. returns true on success
bool AR_AttitudeControl : : get_lat_accel ( float & lat_accel ) const
{
float speed ;
if ( ! get_forward_speed ( speed ) ) {
return false ;
}
lat_accel = speed * _ahrs . get_yaw_rate_earth ( ) ;
return true ;
}
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// return a throttle output from -1 to +1 given a desired speed in m/s (use negative speeds to travel backwards)
// motor_limit should be true if motors have hit their upper or lower limits
// cruise speed should be in m/s, cruise throttle should be a number from -1 to +1
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float AR_AttitudeControl : : get_throttle_out_speed ( float desired_speed , bool motor_limit_low , bool motor_limit_high , float cruise_speed , float cruise_throttle )
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{
// get speed forward
float speed ;
if ( ! get_forward_speed ( speed ) ) {
// we expect caller will not try to control heading using rate control without a valid speed estimate
// on failure to get speed we do not attempt to steer
return 0.0f ;
}
// calculate dt
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const uint32_t now = AP_HAL : : millis ( ) ;
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float dt = ( now - _speed_last_ms ) / 1000.0f ;
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if ( ( _speed_last_ms = = 0 ) | | ( dt > ( AR_ATTCONTROL_TIMEOUT_MS / 1000.0f ) ) ) {
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dt = 0.0f ;
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_throttle_speed_pid . reset_filter ( ) ;
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} else {
_throttle_speed_pid . set_dt ( dt ) ;
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}
_speed_last_ms = now ;
// acceleration limit desired speed
if ( is_positive ( _throttle_accel_max ) ) {
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// reset desired speed to current speed on first iteration
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if ( ! is_positive ( dt ) ) {
desired_speed = speed ;
} else {
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const float speed_change_max = _throttle_accel_max * dt ;
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desired_speed = constrain_float ( desired_speed , _desired_speed - speed_change_max , _desired_speed + speed_change_max ) ;
}
}
// record desired speed for next iteration
_desired_speed = desired_speed ;
// calculate speed error and pass to PID controller
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const float speed_error = desired_speed - speed ;
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_throttle_speed_pid . set_input_filter_all ( speed_error ) ;
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// record desired speed for logging purposes only
_throttle_speed_pid . set_desired_rate ( desired_speed ) ;
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// get feed-forward
const float ff = _throttle_speed_pid . get_ff ( desired_speed ) ;
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// get p
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const float p = _throttle_speed_pid . get_p ( ) ;
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// get i unless moving at low speed or motors have hit a limit
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float i = _throttle_speed_pid . get_integrator ( ) ;
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if ( ( is_negative ( speed_error ) & & ! motor_limit_low & & ! _throttle_limit_low ) | | ( is_positive ( speed_error ) & & ! motor_limit_high & & ! _throttle_limit_high ) ) {
i = _throttle_speed_pid . get_i ( ) ;
}
// get d
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const float d = _throttle_speed_pid . get_d ( ) ;
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// calculate base throttle (protect against divide by zero)
float throttle_base = 0.0f ;
if ( is_positive ( cruise_speed ) & & is_positive ( cruise_throttle ) ) {
throttle_base = desired_speed * ( cruise_throttle / cruise_speed ) ;
}
// calculate final output
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float throttle_out = ( ff + p + i + d + throttle_base ) ;
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// clear local limit flags used to stop i-term build-up as we stop reversed outputs going to motors
_throttle_limit_low = false ;
_throttle_limit_high = false ;
// protect against reverse output being sent to the motors unless braking has been enabled
if ( ! _brake_enable ) {
// if both desired speed and actual speed are positive, do not allow negative values
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if ( ( desired_speed > = 0.0f ) & & ( throttle_out < = 0.0f ) ) {
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throttle_out = 0.0f ;
_throttle_limit_low = true ;
}
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if ( ( desired_speed < = 0.0f ) & & ( throttle_out > = 0.0f ) ) {
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throttle_out = 0.0f ;
_throttle_limit_high = true ;
}
}
// final output throttle in range -1 to 1
return throttle_out ;
}
// return a throttle output from -1 to +1 to perform a controlled stop. returns true once the vehicle has stopped
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float AR_AttitudeControl : : get_throttle_out_stop ( bool motor_limit_low , bool motor_limit_high , float cruise_speed , float cruise_throttle , bool & stopped )
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{
// get current system time
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const uint32_t now = AP_HAL : : millis ( ) ;
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// if we were stopped in the last 300ms, assume we are still stopped
bool _stopped = ( _stop_last_ms ! = 0 ) & & ( now - _stop_last_ms ) < 300 ;
// get speed forward
float speed ;
if ( ! get_forward_speed ( speed ) ) {
// could not get speed so assume stopped
_stopped = true ;
} else {
// if vehicle drops below _stop_speed consider it stopped
if ( fabsf ( speed ) < = fabsf ( _stop_speed ) ) {
_stopped = true ;
}
}
// set stopped status for caller
stopped = _stopped ;
// if stopped return zero
if ( stopped ) {
// update last time we thought we were stopped
_stop_last_ms = now ;
return 0.0f ;
} else {
// clear stopped system time
_stop_last_ms = 0 ;
// run speed controller to bring vehicle to stop
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return get_throttle_out_speed ( 0.0f , motor_limit_low , motor_limit_high , cruise_speed , cruise_throttle ) ;
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}
}
// get forward speed in m/s (earth-frame horizontal velocity but only along vehicle x-axis). returns true on success
bool AR_AttitudeControl : : get_forward_speed ( float & speed ) const
{
Vector3f velocity ;
if ( ! _ahrs . get_velocity_NED ( velocity ) ) {
// use less accurate GPS, assuming entire length is along forward/back axis of vehicle
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if ( AP : : gps ( ) . status ( ) > = AP_GPS : : GPS_OK_FIX_3D ) {
if ( labs ( wrap_180_cd ( _ahrs . yaw_sensor - AP : : gps ( ) . ground_course_cd ( ) ) ) < = 9000 ) {
speed = AP : : gps ( ) . ground_speed ( ) ;
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} else {
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speed = - AP : : gps ( ) . ground_speed ( ) ;
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}
return true ;
} else {
return false ;
}
}
// calculate forward speed velocity into body frame
speed = velocity . x * _ahrs . cos_yaw ( ) + velocity . y * _ahrs . sin_yaw ( ) ;
return true ;
}
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// get latest desired speed recorded during call to get_throttle_out_speed. For reporting purposes only
float AR_AttitudeControl : : get_desired_speed ( ) const
{
// return zero if no recent calls to speed controller
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if ( ( _speed_last_ms = = 0 ) | | ( ( AP_HAL : : millis ( ) - _speed_last_ms ) > AR_ATTCONTROL_TIMEOUT_MS ) ) {
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return 0.0f ;
}
return _desired_speed ;
}