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/// @file AC_PID.cpp
/// @brief Generic PID algorithm
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# include <AP_Math/AP_Math.h>
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# include "AC_PID.h"
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const AP_Param : : GroupInfo AC_PID : : var_info [ ] = {
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// @Param: P
// @DisplayName: PID Proportional Gain
// @Description: P Gain which produces an output value that is proportional to the current error value
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " P " , 0 , AC_PID , _kp , default_kp ) ,
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// @Param: I
// @DisplayName: PID Integral Gain
// @Description: I Gain which produces an output that is proportional to both the magnitude and the duration of the error
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " I " , 1 , AC_PID , _ki , default_ki ) ,
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// @Param: D
// @DisplayName: PID Derivative Gain
// @Description: D Gain which produces an output that is proportional to the rate of change of the error
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " D " , 2 , AC_PID , _kd , default_kd ) ,
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// 3 was for uint16 IMAX
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// @Param: FF
// @DisplayName: FF FeedForward Gain
// @Description: FF Gain which produces an output value that is proportional to the demanded input
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " FF " , 4 , AC_PID , _kff , default_kff ) ,
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// @Param: IMAX
// @DisplayName: PID Integral Maximum
// @Description: The maximum/minimum value that the I term can output
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " IMAX " , 5 , AC_PID , _kimax , default_kimax ) ,
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// 6 was for float FILT
// 7 is for float ILMI and FF
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// index 8 was for AFF
// @Param: FLTT
// @DisplayName: PID Target filter frequency in Hz
// @Description: Target filter frequency in Hz
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// @Units: Hz
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " FLTT " , 9 , AC_PID , _filt_T_hz , default_filt_T_hz ) ,
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// @Param: FLTE
// @DisplayName: PID Error filter frequency in Hz
// @Description: Error filter frequency in Hz
// @Units: Hz
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " FLTE " , 10 , AC_PID , _filt_E_hz , default_filt_E_hz ) ,
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// @Param: FLTD
// @DisplayName: PID Derivative term filter frequency in Hz
// @Description: Derivative filter frequency in Hz
// @Units: Hz
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " FLTD " , 11 , AC_PID , _filt_D_hz , default_filt_D_hz ) ,
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// @Param: SMAX
// @DisplayName: Slew rate limit
// @Description: Sets an upper limit on the slew rate produced by the combined P and D gains. If the amplitude of the control action produced by the rate feedback exceeds this value, then the D+P gain is reduced to respect the limit. This limits the amplitude of high frequency oscillations caused by an excessive gain. The limit should be set to no more than 25% of the actuators maximum slew rate to allow for load effects. Note: The gain will not be reduced to less than 10% of the nominal value. A value of zero will disable this feature.
// @Range: 0 200
// @Increment: 0.5
// @User: Advanced
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AP_GROUPINFO_FLAGS_DEFAULT_POINTER ( " SMAX " , 12 , AC_PID , _slew_rate_max , default_slew_rate_max ) ,
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// @Param: PDMX
// @DisplayName: PD sum maximum
// @Description: The maximum/minimum value that the sum of the P and D term can output
// @User: Advanced
AP_GROUPINFO ( " PDMX " , 13 , AC_PID , _kpdmax , 0 ) ,
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AP_GROUPEND
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} ;
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// Constructor
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AC_PID : : AC_PID ( float initial_p , float initial_i , float initial_d , float initial_ff , float initial_imax , float initial_filt_T_hz , float initial_filt_E_hz , float initial_filt_D_hz ,
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float initial_srmax , float initial_srtau ) :
default_kp ( initial_p ) ,
default_ki ( initial_i ) ,
default_kd ( initial_d ) ,
default_kff ( initial_ff ) ,
default_kimax ( initial_imax ) ,
default_filt_T_hz ( initial_filt_T_hz ) ,
default_filt_E_hz ( initial_filt_E_hz ) ,
default_filt_D_hz ( initial_filt_D_hz ) ,
default_slew_rate_max ( initial_srmax )
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{
// load parameter values from eeprom
AP_Param : : setup_object_defaults ( this , var_info ) ;
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// this param is not in the table, so its default is no loaded in the call above
_slew_rate_tau . set ( initial_srtau ) ;
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// reset input filter to first value received
_flags . _reset_filter = true ;
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memset ( & _pid_info , 0 , sizeof ( _pid_info ) ) ;
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// slew limit scaler allows for plane to use degrees/sec slew
// limit
_slew_limit_scale = 1 ;
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}
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// filt_T_hz - set target filter hz
void AC_PID : : filt_T_hz ( float hz )
{
_filt_T_hz . set ( fabsf ( hz ) ) ;
}
// filt_E_hz - set error filter hz
void AC_PID : : filt_E_hz ( float hz )
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{
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_filt_E_hz . set ( fabsf ( hz ) ) ;
}
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// filt_D_hz - set derivative filter hz
void AC_PID : : filt_D_hz ( float hz )
{
_filt_D_hz . set ( fabsf ( hz ) ) ;
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}
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// slew_limit - set slew limit
void AC_PID : : slew_limit ( float smax )
{
_slew_rate_max . set ( fabsf ( smax ) ) ;
}
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// update_all - set target and measured inputs to PID controller and calculate outputs
// target and error are filtered
// the derivative is then calculated and filtered
// the integral is then updated based on the setting of the limit flag
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float AC_PID : : update_all ( float target , float measurement , float dt , bool limit , float boost )
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{
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// don't process inf or NaN
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if ( ! isfinite ( target ) | | ! isfinite ( measurement ) ) {
return 0.0f ;
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}
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// reset input filter to value received
if ( _flags . _reset_filter ) {
_flags . _reset_filter = false ;
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_target = target ;
_error = _target - measurement ;
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_derivative = 0.0f ;
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} else {
float error_last = _error ;
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_target + = get_filt_T_alpha ( dt ) * ( target - _target ) ;
_error + = get_filt_E_alpha ( dt ) * ( ( _target - measurement ) - _error ) ;
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// calculate and filter derivative
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if ( is_positive ( dt ) ) {
float derivative = ( _error - error_last ) / dt ;
_derivative + = get_filt_D_alpha ( dt ) * ( derivative - _derivative ) ;
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}
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}
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// update I term
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update_i ( dt , limit ) ;
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float P_out = ( _error * _kp ) ;
float D_out = ( _derivative * _kd ) ;
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// calculate slew limit modifier for P+D
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_pid_info . Dmod = _slew_limiter . modifier ( ( _pid_info . P + _pid_info . D ) * _slew_limit_scale , dt ) ;
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_pid_info . slew_rate = _slew_limiter . get_slew_rate ( ) ;
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P_out * = _pid_info . Dmod ;
D_out * = _pid_info . Dmod ;
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// boost output if required
P_out * = boost ;
D_out * = boost ;
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_pid_info . PD_limit = false ;
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// Apply PD sum limit if enabled
if ( is_positive ( _kpdmax ) ) {
const float PD_sum_abs = fabsf ( P_out + D_out ) ;
if ( PD_sum_abs > _kpdmax ) {
const float PD_scale = _kpdmax / PD_sum_abs ;
P_out * = PD_scale ;
D_out * = PD_scale ;
_pid_info . PD_limit = true ;
}
}
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_pid_info . target = _target ;
_pid_info . actual = measurement ;
_pid_info . error = _error ;
_pid_info . P = P_out ;
_pid_info . D = D_out ;
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return P_out + D_out + _integrator ;
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}
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// update_error - set error input to PID controller and calculate outputs
// target is set to zero and error is set and filtered
// the derivative then is calculated and filtered
// the integral is then updated based on the setting of the limit flag
// Target and Measured must be set manually for logging purposes.
// todo: remove function when it is no longer used.
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float AC_PID : : update_error ( float error , float dt , bool limit )
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{
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// don't process inf or NaN
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if ( ! isfinite ( error ) ) {
return 0.0f ;
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}
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// Reuse update all code path, zero target and pass negative error as measurement
// Passing as measurement bypasses any target filtering to maintain behaviour
// Negate as update all calculates error as target - measurement
_target = 0.0 ;
const float output = update_all ( 0.0 , - error , dt , limit ) ;
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// Make sure logged target and actual are still 0 to maintain behaviour
_pid_info . target = 0.0 ;
_pid_info . actual = 0.0 ;
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return output ;
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}
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// update_i - update the integral
// If the limit flag is set the integral is only allowed to shrink
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void AC_PID : : update_i ( float dt , bool limit )
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{
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if ( ! is_zero ( _ki ) & & is_positive ( dt ) ) {
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// Ensure that integrator can only be reduced if the output is saturated
if ( ! limit | | ( ( is_positive ( _integrator ) & & is_negative ( _error ) ) | | ( is_negative ( _integrator ) & & is_positive ( _error ) ) ) ) {
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_integrator + = ( ( float ) _error * _ki ) * dt ;
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_integrator = constrain_float ( _integrator , - _kimax , _kimax ) ;
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}
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} else {
_integrator = 0.0f ;
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}
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_pid_info . I = _integrator ;
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_pid_info . limit = limit ;
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}
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float AC_PID : : get_p ( ) const
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{
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return _error * _kp ;
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}
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float AC_PID : : get_i ( ) const
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{
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return _integrator ;
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}
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float AC_PID : : get_d ( ) const
{
return _kd * _derivative ;
}
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float AC_PID : : get_ff ( )
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{
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_pid_info . FF = _target * _kff ;
return _target * _kff ;
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}
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void AC_PID : : reset_I ( )
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{
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_integrator = 0.0 ;
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}
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void AC_PID : : load_gains ( )
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{
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_kp . load ( ) ;
_ki . load ( ) ;
_kd . load ( ) ;
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_kff . load ( ) ;
_kimax . load ( ) ;
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_kimax . set ( fabsf ( _kimax ) ) ;
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_kpdmax . load ( ) ;
_kpdmax . set ( fabsf ( _kpdmax ) ) ;
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_filt_T_hz . load ( ) ;
_filt_E_hz . load ( ) ;
_filt_D_hz . load ( ) ;
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}
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// save_gains - save gains to eeprom
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void AC_PID : : save_gains ( )
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{
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_kp . save ( ) ;
_ki . save ( ) ;
_kd . save ( ) ;
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_kff . save ( ) ;
_kimax . save ( ) ;
_filt_T_hz . save ( ) ;
_filt_E_hz . save ( ) ;
_filt_D_hz . save ( ) ;
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}
/// Overload the function call operator to permit easy initialisation
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void AC_PID : : operator ( ) ( float p_val , float i_val , float d_val , float ff_val , float imax_val , float input_filt_T_hz , float input_filt_E_hz , float input_filt_D_hz )
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{
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_kp . set ( p_val ) ;
_ki . set ( i_val ) ;
_kd . set ( d_val ) ;
_kff . set ( ff_val ) ;
_kimax . set ( fabsf ( imax_val ) ) ;
_filt_T_hz . set ( input_filt_T_hz ) ;
_filt_E_hz . set ( input_filt_E_hz ) ;
_filt_D_hz . set ( input_filt_D_hz ) ;
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}
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// get_filt_T_alpha - get the target filter alpha
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float AC_PID : : get_filt_T_alpha ( float dt ) const
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{
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return calc_lowpass_alpha_dt ( dt , _filt_T_hz ) ;
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}
// get_filt_E_alpha - get the error filter alpha
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float AC_PID : : get_filt_E_alpha ( float dt ) const
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{
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return calc_lowpass_alpha_dt ( dt , _filt_E_hz ) ;
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}
// get_filt_D_alpha - get the derivative filter alpha
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float AC_PID : : get_filt_D_alpha ( float dt ) const
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{
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return calc_lowpass_alpha_dt ( dt , _filt_D_hz ) ;
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}
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void AC_PID : : set_integrator ( float target , float measurement , float integrator )
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{
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set_integrator ( target - measurement , integrator ) ;
}
void AC_PID : : set_integrator ( float error , float integrator )
{
_integrator = constrain_float ( integrator - error * _kp , - _kimax , _kimax ) ;
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}
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void AC_PID : : set_integrator ( float integrator )
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{
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_integrator = constrain_float ( integrator , - _kimax , _kimax ) ;
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}
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void AC_PID : : relax_integrator ( float integrator , float dt , float time_constant )
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{
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integrator = constrain_float ( integrator , - _kimax , _kimax ) ;
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if ( is_positive ( dt ) ) {
_integrator = _integrator + ( integrator - _integrator ) * ( dt / ( dt + time_constant ) ) ;
}
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}