mirror of https://github.com/ArduPilot/ardupilot
371 lines
10 KiB
C++
371 lines
10 KiB
C++
/// @file AC_PID.cpp
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/// @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
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// @DisplayName: PID Proportional Gain
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// @Description: P Gain which produces an output value that is proportional to the current error value
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AP_GROUPINFO("P", 0, AC_PID, _kp, 0),
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// @Param: I
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// @DisplayName: PID Integral Gain
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// @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("I", 1, AC_PID, _ki, 0),
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// @Param: D
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// @DisplayName: PID Derivative Gain
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// @Description: D Gain which produces an output that is proportional to the rate of change of the error
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AP_GROUPINFO("D", 2, AC_PID, _kd, 0),
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// 3 was for uint16 IMAX
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// @Param: FF
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// @DisplayName: FF FeedForward Gain
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// @Description: FF Gain which produces an output value that is proportional to the demanded input
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AP_GROUPINFO("FF", 4, AC_PID, _kff, 0),
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// @Param: IMAX
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// @DisplayName: PID Integral Maximum
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// @Description: The maximum/minimum value that the I term can output
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AP_GROUPINFO("IMAX", 5, AC_PID, _kimax, 0),
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// 6 was for float FILT
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// 7 is for float ILMI and FF
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// index 8 was for AFF
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// @Param: FLTT
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// @DisplayName: PID Target filter frequency in Hz
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// @Description: Target filter frequency in Hz
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// @Units: Hz
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AP_GROUPINFO("FLTT", 9, AC_PID, _filt_T_hz, AC_PID_TFILT_HZ_DEFAULT),
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// @Param: FLTE
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// @DisplayName: PID Error filter frequency in Hz
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// @Description: Error filter frequency in Hz
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// @Units: Hz
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AP_GROUPINFO("FLTE", 10, AC_PID, _filt_E_hz, AC_PID_EFILT_HZ_DEFAULT),
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// @Param: FLTD
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// @DisplayName: PID Derivative term filter frequency in Hz
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// @Description: Derivative filter frequency in Hz
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// @Units: Hz
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AP_GROUPINFO("FLTD", 11, AC_PID, _filt_D_hz, AC_PID_DFILT_HZ_DEFAULT),
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// @Param: SMAX
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// @DisplayName: Slew rate limit
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// @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.
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// @Range: 0 200
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// @Increment: 0.5
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// @User: Advanced
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AP_GROUPINFO("SMAX", 12, AC_PID, _slew_rate_max, 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 dt, float initial_srmax, float initial_srtau):
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_dt(dt),
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_integrator(0.0f),
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_error(0.0f),
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_derivative(0.0f)
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{
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// load parameter values from eeprom
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AP_Param::setup_object_defaults(this, var_info);
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_kp = initial_p;
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_ki = initial_i;
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_kd = initial_d;
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_kff = initial_ff;
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_kimax = fabsf(initial_imax);
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filt_T_hz(initial_filt_T_hz);
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filt_E_hz(initial_filt_E_hz);
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filt_D_hz(initial_filt_D_hz);
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_slew_rate_max.set(initial_srmax);
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_slew_rate_tau.set(initial_srtau);
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// reset input filter to first value received
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_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
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// limit
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_slew_limit_scale = 1;
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}
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// set_dt - set time step in seconds
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void AC_PID::set_dt(float dt)
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{
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// set dt and calculate the input filter alpha
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_dt = dt;
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}
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// filt_T_hz - set target filter hz
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void AC_PID::filt_T_hz(float hz)
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{
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_filt_T_hz.set(fabsf(hz));
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}
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// filt_E_hz - set error filter hz
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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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}
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// filt_D_hz - set derivative filter hz
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void AC_PID::filt_D_hz(float hz)
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{
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_filt_D_hz.set(fabsf(hz));
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}
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// update_all - set target and measured inputs to PID controller and calculate outputs
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// target and error are filtered
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// the derivative is then calculated and filtered
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// 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, bool limit)
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{
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// don't process inf or NaN
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if (!isfinite(target) || !isfinite(measurement)) {
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return 0.0f;
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}
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// reset input filter to value received
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if (_flags._reset_filter) {
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_flags._reset_filter = false;
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_target = target;
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_error = _target - measurement;
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_derivative = 0.0f;
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} else {
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float error_last = _error;
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_target += get_filt_T_alpha() * (target - _target);
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_error += get_filt_E_alpha() * ((_target - measurement) - _error);
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// calculate and filter derivative
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if (_dt > 0.0f) {
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float derivative = (_error - error_last) / _dt;
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_derivative += get_filt_D_alpha() * (derivative - _derivative);
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}
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}
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// update I term
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update_i(limit);
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float P_out = (_error * _kp);
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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;
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D_out *= _pid_info.Dmod;
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_pid_info.target = _target;
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_pid_info.actual = measurement;
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_pid_info.error = _error;
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_pid_info.P = P_out;
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_pid_info.D = D_out;
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return P_out + _integrator + D_out;
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}
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// update_error - set error input to PID controller and calculate outputs
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// target is set to zero and error is set and filtered
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// the derivative then is calculated and filtered
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// the integral is then updated based on the setting of the limit flag
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// Target and Measured must be set manually for logging purposes.
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// todo: remove function when it is no longer used.
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float AC_PID::update_error(float error, bool limit)
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{
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// don't process inf or NaN
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if (!isfinite(error)) {
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return 0.0f;
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}
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_target = 0.0f;
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// reset input filter to value received
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if (_flags._reset_filter) {
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_flags._reset_filter = false;
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_error = error;
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_derivative = 0.0f;
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} else {
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float error_last = _error;
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_error += get_filt_E_alpha() * (error - _error);
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// calculate and filter derivative
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if (_dt > 0.0f) {
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float derivative = (_error - error_last) / _dt;
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_derivative += get_filt_D_alpha() * (derivative - _derivative);
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}
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}
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// update I term
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update_i(limit);
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float P_out = (_error * _kp);
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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;
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D_out *= _pid_info.Dmod;
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_pid_info.target = 0.0f;
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_pid_info.actual = 0.0f;
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_pid_info.error = _error;
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_pid_info.P = P_out;
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_pid_info.D = D_out;
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return P_out + _integrator + D_out;
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}
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// update_i - update the integral
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// If the limit flag is set the integral is only allowed to shrink
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void AC_PID::update_i(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
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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 {
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_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
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{
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return _kd * _derivative;
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}
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float AC_PID::get_ff()
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{
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_pid_info.FF = _target * _kff;
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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;
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}
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void AC_PID::reset_I_smoothly()
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{
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float reset_time = AC_PID_RESET_TC * 3.0f;
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uint64_t now = AP_HAL::micros64();
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if ((now - _reset_last_update) > 5e5 ) {
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_reset_counter = 0;
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}
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if ((float)_reset_counter < (reset_time/_dt)) {
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_integrator = _integrator - (_dt / (_dt + AC_PID_RESET_TC)) * _integrator;
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_reset_counter++;
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} else {
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_integrator = 0;
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}
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_reset_last_update = now;
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}
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void AC_PID::load_gains()
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{
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_kp.load();
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_ki.load();
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_kd.load();
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_kff.load();
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_kimax.load();
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_kimax = fabsf(_kimax);
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_filt_T_hz.load();
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_filt_E_hz.load();
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_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();
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_ki.save();
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_kd.save();
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_kff.save();
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_kimax.save();
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_filt_T_hz.save();
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_filt_E_hz.save();
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_filt_D_hz.save();
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}
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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, float dt)
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{
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_kp = p_val;
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_ki = i_val;
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_kd = d_val;
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_kff = ff_val;
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_kimax = fabsf(imax_val);
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_filt_T_hz = input_filt_T_hz;
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_filt_E_hz = input_filt_E_hz;
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_filt_D_hz = input_filt_D_hz;
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_dt = dt;
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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() const
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{
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return get_filt_alpha(_filt_T_hz);
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}
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// get_filt_E_alpha - get the error filter alpha
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float AC_PID::get_filt_E_alpha() const
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{
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return get_filt_alpha(_filt_E_hz);
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}
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// get_filt_D_alpha - get the derivative filter alpha
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float AC_PID::get_filt_D_alpha() const
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{
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return get_filt_alpha(_filt_D_hz);
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}
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// get_filt_alpha - calculate a filter alpha
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float AC_PID::get_filt_alpha(float filt_hz) const
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{
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return calc_lowpass_alpha_dt(_dt, filt_hz);
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}
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void AC_PID::set_integrator(float target, float measurement, float i)
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{
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set_integrator(target - measurement, i);
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}
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void AC_PID::set_integrator(float error, float i)
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{
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_integrator = constrain_float(i - error * _kp, -_kimax, _kimax);
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_pid_info.I = _integrator;
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}
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void AC_PID::set_integrator(float i)
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{
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_integrator = constrain_float(i, -_kimax, _kimax);
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_pid_info.I = _integrator;
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}
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