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# include "AC_AutoTune_config.h"
# if AC_AUTOTUNE_ENABLED
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# include "AC_AutoTune_Multi.h"
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# include <AP_Logger/AP_Logger.h>
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# include <AP_Scheduler/AP_Scheduler.h>
# include <GCS_MAVLink/GCS.h>
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/*
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* autotune support for multicopters
*
*
* Instructions :
* 1 ) Set up one flight mode switch position to be AltHold .
* 2 ) Set the Ch7 Opt or Ch8 Opt to AutoTune to allow you to turn the auto tuning on / off with the ch7 or ch8 switch .
* 3 ) Ensure the ch7 or ch8 switch is in the LOW position .
* 4 ) Wait for a calm day and go to a large open area .
* 5 ) Take off and put the vehicle into AltHold mode at a comfortable altitude .
* 6 ) Set the ch7 / ch8 switch to the HIGH position to engage auto tuning :
* a ) You will see it twitch about 20 degrees left and right for a few minutes , then it will repeat forward and back .
* b ) Use the roll and pitch stick at any time to reposition the copter if it drifts away ( it will use the original PID gains during repositioning and between tests ) .
* When you release the sticks it will continue auto tuning where it left off .
* c ) Move the ch7 / ch8 switch into the LOW position at any time to abandon the autotuning and return to the origin PIDs .
* d ) Make sure that you do not have any trim set on your transmitter or the autotune may not get the signal that the sticks are centered .
* 7 ) When the tune completes the vehicle will change back to the original PID gains .
* 8 ) Put the ch7 / ch8 switch into the LOW position then back to the HIGH position to test the tuned PID gains .
* 9 ) Put the ch7 / ch8 switch into the LOW position to fly using the original PID gains .
* 10 ) If you are happy with the autotuned PID gains , leave the ch7 / ch8 switch in the HIGH position , land and disarm to save the PIDs permanently .
* If you DO NOT like the new PIDS , switch ch7 / ch8 LOW to return to the original PIDs . The gains will not be saved when you disarm
*
* What it ' s doing during each " twitch " :
* a ) invokes 90 deg / sec rate request
* b ) records maximum " forward " roll rate and bounce back rate
* c ) when copter reaches 20 degrees or 1 second has passed , it commands level
* d ) tries to keep max rotation rate between 80 % ~ 100 % of requested rate ( 90 deg / sec ) by adjusting rate P
* e ) increases rate D until the bounce back becomes greater than 10 % of requested rate ( 90 deg / sec )
* f ) decreases rate D until the bounce back becomes less than 10 % of requested rate ( 90 deg / sec )
* g ) increases rate P until the max rotate rate becomes greater than the request rate ( 90 deg / sec )
* h ) invokes a 20 deg angle request on roll or pitch
* i ) increases stab P until the maximum angle becomes greater than 110 % of the requested angle ( 20 deg )
* j ) decreases stab P by 25 %
*
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*/
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# define AUTOTUNE_TESTING_STEP_TIMEOUT_MS 2000U // timeout for tuning mode's testing step
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# define AUTOTUNE_RD_STEP 0.05f // minimum increment when increasing/decreasing Rate D term
# define AUTOTUNE_RP_STEP 0.05f // minimum increment when increasing/decreasing Rate P term
# define AUTOTUNE_SP_STEP 0.05f // minimum increment when increasing/decreasing Stab P term
# define AUTOTUNE_PI_RATIO_FOR_TESTING 0.1f // I is set 10x smaller than P during testing
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# define AUTOTUNE_PI_RATIO_FINAL 1.0f // I is set 1x P after testing
# define AUTOTUNE_YAW_PI_RATIO_FINAL 0.1f // I is set 1x P after testing
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# define AUTOTUNE_RD_MAX 0.200f // maximum Rate D value
# define AUTOTUNE_RLPF_MIN 1.0f // minimum Rate Yaw filter value
# define AUTOTUNE_RLPF_MAX 5.0f // maximum Rate Yaw filter value
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# define AUTOTUNE_FLTE_MIN 2.5f // minimum Rate Yaw error filter value
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# define AUTOTUNE_RP_MIN 0.01f // minimum Rate P value
# define AUTOTUNE_RP_MAX 2.0f // maximum Rate P value
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# define AUTOTUNE_SP_MAX 40.0f // maximum Stab P value
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# define AUTOTUNE_SP_MIN 0.5f // maximum Stab P value
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# define AUTOTUNE_RP_ACCEL_MIN 4000.0f // Minimum acceleration for Roll and Pitch
# define AUTOTUNE_Y_ACCEL_MIN 1000.0f // Minimum acceleration for Yaw
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# define AUTOTUNE_Y_FILT_FREQ 10.0f // Autotune filter frequency when testing Yaw
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# define AUTOTUNE_D_UP_DOWN_MARGIN 0.2f // The margin below the target that we tune D in
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# define AUTOTUNE_RD_BACKOFF 1.0f // Rate D gains are reduced to 50% of their maximum value discovered during tuning
# define AUTOTUNE_RP_BACKOFF 1.0f // Rate P gains are reduced to 97.5% of their maximum value discovered during tuning
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# define AUTOTUNE_SP_BACKOFF 0.9f // Stab P gains are reduced to 90% of their maximum value discovered during tuning
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# define AUTOTUNE_ACCEL_RP_BACKOFF 1.0f // back off from maximum acceleration
# define AUTOTUNE_ACCEL_Y_BACKOFF 1.0f // back off from maximum acceleration
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// roll and pitch axes
# define AUTOTUNE_TARGET_RATE_RLLPIT_CDS 18000 // target roll/pitch rate during AUTOTUNE_STEP_TWITCHING step
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# define AUTOTUNE_TARGET_MIN_RATE_RLLPIT_CDS 4500 // target min roll/pitch rate during AUTOTUNE_STEP_TWITCHING step
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// yaw axis
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# define AUTOTUNE_TARGET_RATE_YAW_CDS 9000 // target yaw rate during AUTOTUNE_STEP_TWITCHING step
# define AUTOTUNE_TARGET_MIN_RATE_YAW_CDS 1500 // minimum target yaw rate during AUTOTUNE_STEP_TWITCHING step
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# define AUTOTUNE_TARGET_ANGLE_MAX_RP_SCALE 1.0 / 2.0 // minimum target angle, as a fraction of angle_max, during TESTING_RATE step that will cause us to move to next step
# define AUTOTUNE_TARGET_ANGLE_MAX_Y_SCALE 1.0 // minimum target angle, as a fraction of angle_max, during TESTING_RATE step that will cause us to move to next step
# define AUTOTUNE_TARGET_ANGLE_MIN_RP_SCALE 1.0 / 3.0 // minimum target angle, as a fraction of angle_max, during TESTING_RATE step that will cause us to move to next step
# define AUTOTUNE_TARGET_ANGLE_MIN_Y_SCALE 1.0 / 6.0 // minimum target angle, as a fraction of angle_max, during TESTING_RATE step that will cause us to move to next step
# define AUTOTUNE_ANGLE_ABORT_RP_SCALE 2.5 / 3.0 // maximum allowable angle during testing, as a fraction of angle_max
# define AUTOTUNE_ANGLE_MAX_Y_SCALE 1.0 // maximum allowable angle during testing, as a fraction of angle_max
# define AUTOTUNE_ANGLE_NEG_RP_SCALE 1.0 / 5.0 // maximum allowable angle during testing, as a fraction of angle_max
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// second table of user settable parameters for quadplanes, this
// allows us to go beyond the 64 parameter limit
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const AP_Param : : GroupInfo AC_AutoTune_Multi : : var_info [ ] = {
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// @Param: AXES
// @DisplayName: Autotune axis bitmask
// @Description: 1-byte bitmap of axes to autotune
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// @Bitmask: 0:Roll,1:Pitch,2:Yaw,3:YawD
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// @User: Standard
AP_GROUPINFO ( " AXES " , 1 , AC_AutoTune_Multi , axis_bitmask , 7 ) , // AUTOTUNE_AXIS_BITMASK_DEFAULT
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// @Param: AGGR
// @DisplayName: Autotune aggressiveness
// @Description: Autotune aggressiveness. Defines the bounce back used to detect size of the D term.
// @Range: 0.05 0.10
// @User: Standard
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AP_GROUPINFO ( " AGGR " , 2 , AC_AutoTune_Multi , aggressiveness , 0.075f ) ,
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// @Param: MIN_D
// @DisplayName: AutoTune minimum D
// @Description: Defines the minimum D gain
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// @Range: 0.0001 0.005
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// @User: Standard
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AP_GROUPINFO ( " MIN_D " , 3 , AC_AutoTune_Multi , min_d , 0.0005f ) ,
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AP_GROUPEND
} ;
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// constructor
AC_AutoTune_Multi : : AC_AutoTune_Multi ( )
{
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tune_seq [ 0 ] = TUNE_COMPLETE ;
AP_Param : : setup_object_defaults ( this , var_info ) ;
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}
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void AC_AutoTune_Multi : : do_gcs_announcements ( )
{
const uint32_t now = AP_HAL : : millis ( ) ;
if ( now - announce_time < AUTOTUNE_ANNOUNCE_INTERVAL_MS ) {
return ;
}
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gcs ( ) . send_text ( MAV_SEVERITY_INFO , " AutoTune: %s %s %u%% " , axis_string ( ) , type_string ( ) , ( counter * ( 100 / AUTOTUNE_SUCCESS_COUNT ) ) ) ;
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announce_time = now ;
}
void AC_AutoTune_Multi : : test_init ( )
{
twitch_test_init ( ) ;
}
void AC_AutoTune_Multi : : test_run ( AxisType test_axis , const float dir_sign )
{
twitch_test_run ( test_axis , dir_sign ) ;
}
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// backup_gains_and_initialise - store current gains as originals
// called before tuning starts to backup original gains
void AC_AutoTune_Multi : : backup_gains_and_initialise ( )
{
AC_AutoTune : : backup_gains_and_initialise ( ) ;
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aggressiveness . set ( constrain_float ( aggressiveness , 0.05f , 0.2f ) ) ;
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orig_bf_feedforward = attitude_control - > get_bf_feedforward ( ) ;
// backup original pids and initialise tuned pid values
orig_roll_rp = attitude_control - > get_rate_roll_pid ( ) . kP ( ) ;
orig_roll_ri = attitude_control - > get_rate_roll_pid ( ) . kI ( ) ;
orig_roll_rd = attitude_control - > get_rate_roll_pid ( ) . kD ( ) ;
orig_roll_rff = attitude_control - > get_rate_roll_pid ( ) . ff ( ) ;
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orig_roll_dff = attitude_control - > get_rate_roll_pid ( ) . kDff ( ) ;
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orig_roll_fltt = attitude_control - > get_rate_roll_pid ( ) . filt_T_hz ( ) ;
orig_roll_smax = attitude_control - > get_rate_roll_pid ( ) . slew_limit ( ) ;
orig_roll_sp = attitude_control - > get_angle_roll_p ( ) . kP ( ) ;
orig_roll_accel = attitude_control - > get_accel_roll_max_cdss ( ) ;
tune_roll_rp = attitude_control - > get_rate_roll_pid ( ) . kP ( ) ;
tune_roll_rd = attitude_control - > get_rate_roll_pid ( ) . kD ( ) ;
tune_roll_sp = attitude_control - > get_angle_roll_p ( ) . kP ( ) ;
tune_roll_accel = attitude_control - > get_accel_roll_max_cdss ( ) ;
orig_pitch_rp = attitude_control - > get_rate_pitch_pid ( ) . kP ( ) ;
orig_pitch_ri = attitude_control - > get_rate_pitch_pid ( ) . kI ( ) ;
orig_pitch_rd = attitude_control - > get_rate_pitch_pid ( ) . kD ( ) ;
orig_pitch_rff = attitude_control - > get_rate_pitch_pid ( ) . ff ( ) ;
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orig_pitch_dff = attitude_control - > get_rate_pitch_pid ( ) . kDff ( ) ;
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orig_pitch_fltt = attitude_control - > get_rate_pitch_pid ( ) . filt_T_hz ( ) ;
orig_pitch_smax = attitude_control - > get_rate_pitch_pid ( ) . slew_limit ( ) ;
orig_pitch_sp = attitude_control - > get_angle_pitch_p ( ) . kP ( ) ;
orig_pitch_accel = attitude_control - > get_accel_pitch_max_cdss ( ) ;
tune_pitch_rp = attitude_control - > get_rate_pitch_pid ( ) . kP ( ) ;
tune_pitch_rd = attitude_control - > get_rate_pitch_pid ( ) . kD ( ) ;
tune_pitch_sp = attitude_control - > get_angle_pitch_p ( ) . kP ( ) ;
tune_pitch_accel = attitude_control - > get_accel_pitch_max_cdss ( ) ;
orig_yaw_rp = attitude_control - > get_rate_yaw_pid ( ) . kP ( ) ;
orig_yaw_ri = attitude_control - > get_rate_yaw_pid ( ) . kI ( ) ;
orig_yaw_rd = attitude_control - > get_rate_yaw_pid ( ) . kD ( ) ;
orig_yaw_rff = attitude_control - > get_rate_yaw_pid ( ) . ff ( ) ;
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orig_yaw_dff = attitude_control - > get_rate_yaw_pid ( ) . kDff ( ) ;
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orig_yaw_fltt = attitude_control - > get_rate_yaw_pid ( ) . filt_T_hz ( ) ;
orig_yaw_smax = attitude_control - > get_rate_yaw_pid ( ) . slew_limit ( ) ;
orig_yaw_rLPF = attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( ) ;
orig_yaw_accel = attitude_control - > get_accel_yaw_max_cdss ( ) ;
orig_yaw_sp = attitude_control - > get_angle_yaw_p ( ) . kP ( ) ;
tune_yaw_rp = attitude_control - > get_rate_yaw_pid ( ) . kP ( ) ;
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tune_yaw_rd = attitude_control - > get_rate_yaw_pid ( ) . kD ( ) ;
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tune_yaw_rLPF = attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( ) ;
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if ( yaw_d_enabled ( ) & & is_zero ( tune_yaw_rd ) ) {
tune_yaw_rd = min_d ;
}
if ( yaw_enabled ( ) & & is_zero ( tune_yaw_rLPF ) ) {
tune_yaw_rLPF = AUTOTUNE_FLTE_MIN ;
}
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tune_yaw_sp = attitude_control - > get_angle_yaw_p ( ) . kP ( ) ;
tune_yaw_accel = attitude_control - > get_accel_yaw_max_cdss ( ) ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_INITIALISED ) ;
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}
// load_orig_gains - set gains to their original values
// called by stop and failed functions
void AC_AutoTune_Multi : : load_orig_gains ( )
{
attitude_control - > bf_feedforward ( orig_bf_feedforward ) ;
if ( roll_enabled ( ) ) {
if ( ! is_zero ( orig_roll_rp ) ) {
attitude_control - > get_rate_roll_pid ( ) . kP ( orig_roll_rp ) ;
attitude_control - > get_rate_roll_pid ( ) . kI ( orig_roll_ri ) ;
attitude_control - > get_rate_roll_pid ( ) . kD ( orig_roll_rd ) ;
attitude_control - > get_rate_roll_pid ( ) . ff ( orig_roll_rff ) ;
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attitude_control - > get_rate_roll_pid ( ) . kDff ( orig_roll_dff ) ;
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attitude_control - > get_rate_roll_pid ( ) . filt_T_hz ( orig_roll_fltt ) ;
attitude_control - > get_rate_roll_pid ( ) . slew_limit ( orig_roll_smax ) ;
attitude_control - > get_angle_roll_p ( ) . kP ( orig_roll_sp ) ;
attitude_control - > set_accel_roll_max_cdss ( orig_roll_accel ) ;
}
}
if ( pitch_enabled ( ) ) {
if ( ! is_zero ( orig_pitch_rp ) ) {
attitude_control - > get_rate_pitch_pid ( ) . kP ( orig_pitch_rp ) ;
attitude_control - > get_rate_pitch_pid ( ) . kI ( orig_pitch_ri ) ;
attitude_control - > get_rate_pitch_pid ( ) . kD ( orig_pitch_rd ) ;
attitude_control - > get_rate_pitch_pid ( ) . ff ( orig_pitch_rff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kDff ( orig_pitch_dff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . filt_T_hz ( orig_pitch_fltt ) ;
attitude_control - > get_rate_pitch_pid ( ) . slew_limit ( orig_pitch_smax ) ;
attitude_control - > get_angle_pitch_p ( ) . kP ( orig_pitch_sp ) ;
attitude_control - > set_accel_pitch_max_cdss ( orig_pitch_accel ) ;
}
}
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if ( yaw_enabled ( ) | | yaw_d_enabled ( ) ) {
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if ( ! is_zero ( orig_yaw_rp ) ) {
attitude_control - > get_rate_yaw_pid ( ) . kP ( orig_yaw_rp ) ;
attitude_control - > get_rate_yaw_pid ( ) . kI ( orig_yaw_ri ) ;
attitude_control - > get_rate_yaw_pid ( ) . kD ( orig_yaw_rd ) ;
attitude_control - > get_rate_yaw_pid ( ) . ff ( orig_yaw_rff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . kDff ( orig_yaw_dff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( orig_yaw_rLPF ) ;
attitude_control - > get_rate_yaw_pid ( ) . filt_T_hz ( orig_yaw_fltt ) ;
attitude_control - > get_rate_yaw_pid ( ) . slew_limit ( orig_yaw_smax ) ;
attitude_control - > get_angle_yaw_p ( ) . kP ( orig_yaw_sp ) ;
attitude_control - > set_accel_yaw_max_cdss ( orig_yaw_accel ) ;
}
}
}
// load_tuned_gains - load tuned gains
void AC_AutoTune_Multi : : load_tuned_gains ( )
{
if ( ! attitude_control - > get_bf_feedforward ( ) ) {
attitude_control - > bf_feedforward ( true ) ;
attitude_control - > set_accel_roll_max_cdss ( 0.0f ) ;
attitude_control - > set_accel_pitch_max_cdss ( 0.0f ) ;
}
if ( roll_enabled ( ) ) {
if ( ! is_zero ( tune_roll_rp ) ) {
attitude_control - > get_rate_roll_pid ( ) . kP ( tune_roll_rp ) ;
attitude_control - > get_rate_roll_pid ( ) . kI ( tune_roll_rp * AUTOTUNE_PI_RATIO_FINAL ) ;
attitude_control - > get_rate_roll_pid ( ) . kD ( tune_roll_rd ) ;
attitude_control - > get_rate_roll_pid ( ) . ff ( orig_roll_rff ) ;
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attitude_control - > get_rate_roll_pid ( ) . kDff ( orig_roll_dff ) ;
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attitude_control - > get_angle_roll_p ( ) . kP ( tune_roll_sp ) ;
attitude_control - > set_accel_roll_max_cdss ( tune_roll_accel ) ;
}
}
if ( pitch_enabled ( ) ) {
if ( ! is_zero ( tune_pitch_rp ) ) {
attitude_control - > get_rate_pitch_pid ( ) . kP ( tune_pitch_rp ) ;
attitude_control - > get_rate_pitch_pid ( ) . kI ( tune_pitch_rp * AUTOTUNE_PI_RATIO_FINAL ) ;
attitude_control - > get_rate_pitch_pid ( ) . kD ( tune_pitch_rd ) ;
attitude_control - > get_rate_pitch_pid ( ) . ff ( orig_pitch_rff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kDff ( orig_pitch_dff ) ;
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attitude_control - > get_angle_pitch_p ( ) . kP ( tune_pitch_sp ) ;
attitude_control - > set_accel_pitch_max_cdss ( tune_pitch_accel ) ;
}
}
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if ( yaw_enabled ( ) | | yaw_d_enabled ( ) ) {
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if ( ! is_zero ( tune_yaw_rp ) ) {
attitude_control - > get_rate_yaw_pid ( ) . kP ( tune_yaw_rp ) ;
attitude_control - > get_rate_yaw_pid ( ) . kI ( tune_yaw_rp * AUTOTUNE_YAW_PI_RATIO_FINAL ) ;
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if ( yaw_d_enabled ( ) ) {
attitude_control - > get_rate_yaw_pid ( ) . kD ( tune_yaw_rd ) ;
}
if ( yaw_enabled ( ) ) {
attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( tune_yaw_rLPF ) ;
}
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attitude_control - > get_rate_yaw_pid ( ) . ff ( orig_yaw_rff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . kDff ( orig_yaw_dff ) ;
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attitude_control - > get_angle_yaw_p ( ) . kP ( tune_yaw_sp ) ;
attitude_control - > set_accel_yaw_max_cdss ( tune_yaw_accel ) ;
}
}
}
// load_intra_test_gains - gains used between tests
// called during testing mode's update-gains step to set gains ahead of return-to-level step
void AC_AutoTune_Multi : : load_intra_test_gains ( )
{
// we are restarting tuning so reset gains to tuning-start gains (i.e. low I term)
// sanity check the gains
attitude_control - > bf_feedforward ( true ) ;
if ( roll_enabled ( ) ) {
attitude_control - > get_rate_roll_pid ( ) . kP ( orig_roll_rp ) ;
attitude_control - > get_rate_roll_pid ( ) . kI ( orig_roll_rp * AUTOTUNE_PI_RATIO_FOR_TESTING ) ;
attitude_control - > get_rate_roll_pid ( ) . kD ( orig_roll_rd ) ;
attitude_control - > get_rate_roll_pid ( ) . ff ( orig_roll_rff ) ;
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attitude_control - > get_rate_roll_pid ( ) . kDff ( orig_roll_dff ) ;
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attitude_control - > get_rate_roll_pid ( ) . filt_T_hz ( orig_roll_fltt ) ;
attitude_control - > get_rate_roll_pid ( ) . slew_limit ( orig_roll_smax ) ;
attitude_control - > get_angle_roll_p ( ) . kP ( orig_roll_sp ) ;
}
if ( pitch_enabled ( ) ) {
attitude_control - > get_rate_pitch_pid ( ) . kP ( orig_pitch_rp ) ;
attitude_control - > get_rate_pitch_pid ( ) . kI ( orig_pitch_rp * AUTOTUNE_PI_RATIO_FOR_TESTING ) ;
attitude_control - > get_rate_pitch_pid ( ) . kD ( orig_pitch_rd ) ;
attitude_control - > get_rate_pitch_pid ( ) . ff ( orig_pitch_rff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kDff ( orig_pitch_dff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . filt_T_hz ( orig_pitch_fltt ) ;
attitude_control - > get_rate_pitch_pid ( ) . slew_limit ( orig_pitch_smax ) ;
attitude_control - > get_angle_pitch_p ( ) . kP ( orig_pitch_sp ) ;
}
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if ( yaw_enabled ( ) | | yaw_d_enabled ( ) ) {
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attitude_control - > get_rate_yaw_pid ( ) . kP ( orig_yaw_rp ) ;
attitude_control - > get_rate_yaw_pid ( ) . kI ( orig_yaw_rp * AUTOTUNE_PI_RATIO_FOR_TESTING ) ;
attitude_control - > get_rate_yaw_pid ( ) . kD ( orig_yaw_rd ) ;
attitude_control - > get_rate_yaw_pid ( ) . ff ( orig_yaw_rff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . kDff ( orig_yaw_dff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . filt_T_hz ( orig_yaw_fltt ) ;
attitude_control - > get_rate_yaw_pid ( ) . slew_limit ( orig_yaw_smax ) ;
attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( orig_yaw_rLPF ) ;
attitude_control - > get_angle_yaw_p ( ) . kP ( orig_yaw_sp ) ;
}
}
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// load_test_gains - load the to-be-tested gains for a single axis
// called by control_attitude() just before it beings testing a gain (i.e. just before it twitches)
void AC_AutoTune_Multi : : load_test_gains ( )
{
switch ( axis ) {
case ROLL :
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attitude_control - > get_rate_roll_pid ( ) . kP ( tune_roll_rp ) ;
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attitude_control - > get_rate_roll_pid ( ) . kI ( tune_roll_rp * 0.01f ) ;
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attitude_control - > get_rate_roll_pid ( ) . kD ( tune_roll_rd ) ;
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attitude_control - > get_rate_roll_pid ( ) . ff ( 0.0f ) ;
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attitude_control - > get_rate_roll_pid ( ) . kDff ( 0.0f ) ;
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attitude_control - > get_rate_roll_pid ( ) . filt_T_hz ( 0.0f ) ;
attitude_control - > get_rate_roll_pid ( ) . slew_limit ( 0.0f ) ;
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attitude_control - > get_angle_roll_p ( ) . kP ( tune_roll_sp ) ;
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break ;
case PITCH :
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attitude_control - > get_rate_pitch_pid ( ) . kP ( tune_pitch_rp ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kI ( tune_pitch_rp * 0.01f ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kD ( tune_pitch_rd ) ;
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attitude_control - > get_rate_pitch_pid ( ) . ff ( 0.0f ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kDff ( 0.0f ) ;
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attitude_control - > get_rate_pitch_pid ( ) . filt_T_hz ( 0.0f ) ;
attitude_control - > get_rate_pitch_pid ( ) . slew_limit ( 0.0f ) ;
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attitude_control - > get_angle_pitch_p ( ) . kP ( tune_pitch_sp ) ;
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break ;
case YAW :
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case YAW_D :
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attitude_control - > get_rate_yaw_pid ( ) . kP ( tune_yaw_rp ) ;
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attitude_control - > get_rate_yaw_pid ( ) . kI ( tune_yaw_rp * 0.01f ) ;
attitude_control - > get_rate_yaw_pid ( ) . ff ( 0.0f ) ;
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attitude_control - > get_rate_yaw_pid ( ) . kDff ( 0.0f ) ;
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if ( axis = = YAW_D ) {
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attitude_control - > get_rate_yaw_pid ( ) . kD ( tune_yaw_rd ) ;
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} else {
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attitude_control - > get_rate_yaw_pid ( ) . kD ( 0.0 ) ;
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attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( tune_yaw_rLPF ) ;
}
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attitude_control - > get_rate_yaw_pid ( ) . filt_T_hz ( 0.0f ) ;
attitude_control - > get_rate_yaw_pid ( ) . slew_limit ( 0.0f ) ;
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attitude_control - > get_angle_yaw_p ( ) . kP ( tune_yaw_sp ) ;
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break ;
}
}
// save_tuning_gains - save the final tuned gains for each axis
// save discovered gains to eeprom if autotuner is enabled (i.e. switch is in the high position)
void AC_AutoTune_Multi : : save_tuning_gains ( )
{
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// see if we successfully completed tuning of at least one axis
if ( axes_completed = = 0 ) {
return ;
}
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if ( ! attitude_control - > get_bf_feedforward ( ) ) {
attitude_control - > bf_feedforward_save ( true ) ;
attitude_control - > save_accel_roll_max_cdss ( 0.0f ) ;
attitude_control - > save_accel_pitch_max_cdss ( 0.0f ) ;
}
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// sanity check the rate P values
if ( ( axes_completed & AUTOTUNE_AXIS_BITMASK_ROLL ) & & roll_enabled ( ) & & ! is_zero ( tune_roll_rp ) ) {
// rate roll gains
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attitude_control - > get_rate_roll_pid ( ) . kP ( tune_roll_rp ) ;
attitude_control - > get_rate_roll_pid ( ) . kI ( tune_roll_rp * AUTOTUNE_PI_RATIO_FINAL ) ;
attitude_control - > get_rate_roll_pid ( ) . kD ( tune_roll_rd ) ;
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attitude_control - > get_rate_roll_pid ( ) . ff ( orig_roll_rff ) ;
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attitude_control - > get_rate_roll_pid ( ) . kDff ( orig_roll_dff ) ;
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attitude_control - > get_rate_roll_pid ( ) . filt_T_hz ( orig_roll_fltt ) ;
attitude_control - > get_rate_roll_pid ( ) . slew_limit ( orig_roll_smax ) ;
attitude_control - > get_rate_roll_pid ( ) . save_gains ( ) ;
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// stabilize roll
attitude_control - > get_angle_roll_p ( ) . kP ( tune_roll_sp ) ;
attitude_control - > get_angle_roll_p ( ) . save_gains ( ) ;
// acceleration roll
attitude_control - > save_accel_roll_max_cdss ( tune_roll_accel ) ;
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// resave pids to originals in case the autotune is run again
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orig_roll_rp = attitude_control - > get_rate_roll_pid ( ) . kP ( ) ;
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orig_roll_ri = attitude_control - > get_rate_roll_pid ( ) . kI ( ) ;
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orig_roll_rd = attitude_control - > get_rate_roll_pid ( ) . kD ( ) ;
orig_roll_rff = attitude_control - > get_rate_roll_pid ( ) . ff ( ) ;
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orig_roll_dff = attitude_control - > get_rate_roll_pid ( ) . kDff ( ) ;
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orig_roll_sp = attitude_control - > get_angle_roll_p ( ) . kP ( ) ;
orig_roll_accel = attitude_control - > get_accel_roll_max_cdss ( ) ;
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}
if ( ( axes_completed & AUTOTUNE_AXIS_BITMASK_PITCH ) & & pitch_enabled ( ) & & ! is_zero ( tune_pitch_rp ) ) {
// rate pitch gains
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attitude_control - > get_rate_pitch_pid ( ) . kP ( tune_pitch_rp ) ;
attitude_control - > get_rate_pitch_pid ( ) . kI ( tune_pitch_rp * AUTOTUNE_PI_RATIO_FINAL ) ;
attitude_control - > get_rate_pitch_pid ( ) . kD ( tune_pitch_rd ) ;
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attitude_control - > get_rate_pitch_pid ( ) . ff ( orig_pitch_rff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . kDff ( orig_pitch_dff ) ;
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attitude_control - > get_rate_pitch_pid ( ) . filt_T_hz ( orig_pitch_fltt ) ;
attitude_control - > get_rate_pitch_pid ( ) . slew_limit ( orig_pitch_smax ) ;
attitude_control - > get_rate_pitch_pid ( ) . save_gains ( ) ;
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// stabilize pitch
attitude_control - > get_angle_pitch_p ( ) . kP ( tune_pitch_sp ) ;
attitude_control - > get_angle_pitch_p ( ) . save_gains ( ) ;
// acceleration pitch
attitude_control - > save_accel_pitch_max_cdss ( tune_pitch_accel ) ;
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// resave pids to originals in case the autotune is run again
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orig_pitch_rp = attitude_control - > get_rate_pitch_pid ( ) . kP ( ) ;
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orig_pitch_ri = attitude_control - > get_rate_pitch_pid ( ) . kI ( ) ;
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orig_pitch_rd = attitude_control - > get_rate_pitch_pid ( ) . kD ( ) ;
orig_pitch_rff = attitude_control - > get_rate_pitch_pid ( ) . ff ( ) ;
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orig_pitch_dff = attitude_control - > get_rate_pitch_pid ( ) . kDff ( ) ;
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orig_pitch_sp = attitude_control - > get_angle_pitch_p ( ) . kP ( ) ;
orig_pitch_accel = attitude_control - > get_accel_pitch_max_cdss ( ) ;
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}
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if ( ( ( ( axes_completed & AUTOTUNE_AXIS_BITMASK_YAW ) & & yaw_enabled ( ) )
| | ( ( axes_completed & AUTOTUNE_AXIS_BITMASK_YAW_D ) & & yaw_d_enabled ( ) ) ) & & ! is_zero ( tune_yaw_rp ) ) {
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// rate yaw gains
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attitude_control - > get_rate_yaw_pid ( ) . kP ( tune_yaw_rp ) ;
attitude_control - > get_rate_yaw_pid ( ) . kI ( tune_yaw_rp * AUTOTUNE_YAW_PI_RATIO_FINAL ) ;
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attitude_control - > get_rate_yaw_pid ( ) . ff ( orig_yaw_rff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . kDff ( orig_yaw_dff ) ;
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attitude_control - > get_rate_yaw_pid ( ) . filt_T_hz ( orig_yaw_fltt ) ;
attitude_control - > get_rate_yaw_pid ( ) . slew_limit ( orig_yaw_smax ) ;
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if ( yaw_d_enabled ( ) ) {
attitude_control - > get_rate_yaw_pid ( ) . kD ( tune_yaw_rd ) ;
}
if ( yaw_enabled ( ) ) {
attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( tune_yaw_rLPF ) ;
}
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attitude_control - > get_rate_yaw_pid ( ) . save_gains ( ) ;
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// stabilize yaw
attitude_control - > get_angle_yaw_p ( ) . kP ( tune_yaw_sp ) ;
attitude_control - > get_angle_yaw_p ( ) . save_gains ( ) ;
// acceleration yaw
attitude_control - > save_accel_yaw_max_cdss ( tune_yaw_accel ) ;
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// resave pids to originals in case the autotune is run again
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orig_yaw_rp = attitude_control - > get_rate_yaw_pid ( ) . kP ( ) ;
orig_yaw_ri = attitude_control - > get_rate_yaw_pid ( ) . kI ( ) ;
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orig_yaw_rd = attitude_control - > get_rate_yaw_pid ( ) . kD ( ) ;
orig_yaw_rff = attitude_control - > get_rate_yaw_pid ( ) . ff ( ) ;
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orig_yaw_dff = attitude_control - > get_rate_yaw_pid ( ) . kDff ( ) ;
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orig_yaw_rLPF = attitude_control - > get_rate_yaw_pid ( ) . filt_E_hz ( ) ;
orig_yaw_sp = attitude_control - > get_angle_yaw_p ( ) . kP ( ) ;
orig_yaw_accel = attitude_control - > get_accel_yaw_max_cdss ( ) ;
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}
// update GCS and log save gains event
update_gcs ( AUTOTUNE_MESSAGE_SAVED_GAINS ) ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_SAVEDGAINS ) ;
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reset ( ) ;
}
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// report final gains for a given axis to GCS
void AC_AutoTune_Multi : : report_final_gains ( AxisType test_axis ) const
{
switch ( test_axis ) {
case ROLL :
report_axis_gains ( " Roll " , tune_roll_rp , tune_roll_rp * AUTOTUNE_PI_RATIO_FINAL , tune_roll_rd , tune_roll_sp , tune_roll_accel ) ;
break ;
case PITCH :
report_axis_gains ( " Pitch " , tune_pitch_rp , tune_pitch_rp * AUTOTUNE_PI_RATIO_FINAL , tune_pitch_rd , tune_pitch_sp , tune_pitch_accel ) ;
break ;
case YAW :
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report_axis_gains ( " Yaw(E) " , tune_yaw_rp , tune_yaw_rp * AUTOTUNE_YAW_PI_RATIO_FINAL , 0 , tune_yaw_sp , tune_yaw_accel ) ;
break ;
case YAW_D :
report_axis_gains ( " Yaw(D) " , tune_yaw_rp , tune_yaw_rp * AUTOTUNE_YAW_PI_RATIO_FINAL , tune_yaw_rd , tune_yaw_sp , tune_yaw_accel ) ;
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break ;
}
}
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// report gain formatting helper
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void AC_AutoTune_Multi : : report_axis_gains ( const char * axis_string , float rate_P , float rate_I , float rate_D , float angle_P , float max_accel ) const
{
gcs ( ) . send_text ( MAV_SEVERITY_NOTICE , " AutoTune: %s complete " , axis_string ) ;
gcs ( ) . send_text ( MAV_SEVERITY_NOTICE , " AutoTune: %s Rate: P:%0.3f, I:%0.3f, D:%0.4f " , axis_string , rate_P , rate_I , rate_D ) ;
gcs ( ) . send_text ( MAV_SEVERITY_NOTICE , " AutoTune: %s Angle P:%0.3f, Max Accel:%0.0f " , axis_string , angle_P , max_accel ) ;
}
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// twitching_test_rate - twitching tests
// update min and max and test for end conditions
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void AC_AutoTune_Multi : : twitching_test_rate ( float angle , float rate , float rate_target_max , float & meas_rate_min , float & meas_rate_max , float & meas_angle_min )
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{
const uint32_t now = AP_HAL : : millis ( ) ;
// capture maximum rate
if ( rate > meas_rate_max ) {
// the measurement is continuing to increase without stopping
meas_rate_max = rate ;
meas_rate_min = rate ;
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meas_angle_min = angle ;
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}
// capture minimum measurement after the measurement has peaked (aka "bounce back")
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if ( ( rate < meas_rate_min ) & & ( meas_rate_max > rate_target_max * 0.25 ) ) {
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// the measurement is bouncing back
meas_rate_min = rate ;
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meas_angle_min = angle ;
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}
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// calculate early stopping time based on the time it takes to get to 63.21%
if ( meas_rate_max < rate_target_max * 0.6321 ) {
// the measurement not reached the 63.21% threshold yet
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step_time_limit_ms = ( now - step_start_time_ms ) * 3 ;
step_time_limit_ms = MIN ( step_time_limit_ms , AUTOTUNE_TESTING_STEP_TIMEOUT_MS ) ;
}
if ( meas_rate_max > rate_target_max ) {
// the measured rate has passed the maximum target rate
step = UPDATE_GAINS ;
}
if ( meas_rate_max - meas_rate_min > meas_rate_max * aggressiveness ) {
// the measurement has passed 50% of the maximum rate and bounce back is larger than the threshold
step = UPDATE_GAINS ;
}
if ( now - step_start_time_ms > = step_time_limit_ms ) {
// we have passed the maximum stop time
step = UPDATE_GAINS ;
}
}
// twitching_test_rate - twitching tests
// update min and max and test for end conditions
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void AC_AutoTune_Multi : : twitching_abort_rate ( float angle , float rate , float angle_max , float meas_rate_min , float angle_min )
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{
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const uint32_t now = AP_HAL : : millis ( ) ;
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if ( angle > = angle_max ) {
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if ( is_equal ( rate , meas_rate_min ) | | ( angle_min > 0.95 * angle_max ) ) {
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// we have reached the angle limit before completing the measurement of maximum and minimum
// reduce the maximum target rate
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if ( step_scaler > 0.2f ) {
step_scaler * = 0.9f ;
} else {
LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " AutoTune: Twitch Size Determination Failed " ) ;
mode = FAILED ;
LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_FAILED ) ;
}
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// ignore result and start test again
step = WAITING_FOR_LEVEL ;
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positive_direction = twitch_reverse_direction ( ) ;
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step_start_time_ms = now ;
level_start_time_ms = now ;
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} else {
step = UPDATE_GAINS ;
}
}
}
// twitching_test_angle - twitching tests
// update min and max and test for end conditions
void AC_AutoTune_Multi : : twitching_test_angle ( float angle , float rate , float angle_target_max , float & meas_angle_min , float & meas_angle_max , float & meas_rate_min , float & meas_rate_max )
{
const uint32_t now = AP_HAL : : millis ( ) ;
// capture maximum angle
if ( angle > meas_angle_max ) {
// the angle still increasing
meas_angle_max = angle ;
meas_angle_min = angle ;
}
// capture minimum angle after we have reached a reasonable maximum angle
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if ( ( angle < meas_angle_min ) & & ( meas_angle_max > angle_target_max * 0.25 ) ) {
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// the measurement is bouncing back
meas_angle_min = angle ;
}
// capture maximum rate
if ( rate > meas_rate_max ) {
// the measurement is still increasing
meas_rate_max = rate ;
meas_rate_min = rate ;
}
// capture minimum rate after we have reached maximum rate
if ( rate < meas_rate_min ) {
// the measurement is still decreasing
meas_rate_min = rate ;
}
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// calculate early stopping time based on the time it takes to get to 63.21%
if ( meas_angle_max < angle_target_max * 0.6321 ) {
// the measurement not reached the 63.21% threshold yet
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step_time_limit_ms = ( now - step_start_time_ms ) * 3 ;
step_time_limit_ms = MIN ( step_time_limit_ms , AUTOTUNE_TESTING_STEP_TIMEOUT_MS ) ;
}
if ( meas_angle_max > angle_target_max ) {
// the measurement has passed the maximum angle
step = UPDATE_GAINS ;
}
if ( meas_angle_max - meas_angle_min > meas_angle_max * aggressiveness ) {
// the measurement has passed 50% of the maximum angle and bounce back is larger than the threshold
step = UPDATE_GAINS ;
}
if ( now - step_start_time_ms > = step_time_limit_ms ) {
// we have passed the maximum stop time
step = UPDATE_GAINS ;
}
}
// twitching_measure_acceleration - measure rate of change of measurement
void AC_AutoTune_Multi : : twitching_measure_acceleration ( float & rate_of_change , float rate_measurement , float & rate_measurement_max ) const
{
if ( rate_measurement_max < rate_measurement ) {
rate_measurement_max = rate_measurement ;
rate_of_change = ( 1000.0f * rate_measurement_max ) / ( AP_HAL : : millis ( ) - step_start_time_ms ) ;
}
}
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// update gains for the rate p up tune type
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void AC_AutoTune_Multi : : updating_rate_p_up_all ( AxisType test_axis )
{
switch ( test_axis ) {
case ROLL :
updating_rate_p_up_d_down ( tune_roll_rd , min_d , AUTOTUNE_RD_STEP , tune_roll_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
case PITCH :
updating_rate_p_up_d_down ( tune_pitch_rd , min_d , AUTOTUNE_RD_STEP , tune_pitch_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
case YAW :
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updating_rate_p_up_d_down ( tune_yaw_rLPF , AUTOTUNE_RLPF_MIN , AUTOTUNE_RD_STEP , tune_yaw_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max , false ) ;
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break ;
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case YAW_D :
updating_rate_p_up_d_down ( tune_yaw_rd , min_d , AUTOTUNE_RD_STEP , tune_yaw_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
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}
}
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// update gains for the rate d up tune type
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void AC_AutoTune_Multi : : updating_rate_d_up_all ( AxisType test_axis )
{
switch ( test_axis ) {
case ROLL :
updating_rate_d_up ( tune_roll_rd , min_d , AUTOTUNE_RD_MAX , AUTOTUNE_RD_STEP , tune_roll_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
case PITCH :
updating_rate_d_up ( tune_pitch_rd , min_d , AUTOTUNE_RD_MAX , AUTOTUNE_RD_STEP , tune_pitch_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
case YAW :
updating_rate_d_up ( tune_yaw_rLPF , AUTOTUNE_RLPF_MIN , AUTOTUNE_RLPF_MAX , AUTOTUNE_RD_STEP , tune_yaw_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
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case YAW_D :
updating_rate_d_up ( tune_yaw_rd , min_d , AUTOTUNE_RD_MAX , AUTOTUNE_RD_STEP , tune_yaw_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
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}
}
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// update gains for the rate d down tune type
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void AC_AutoTune_Multi : : updating_rate_d_down_all ( AxisType test_axis )
{
switch ( test_axis ) {
case ROLL :
updating_rate_d_down ( tune_roll_rd , min_d , AUTOTUNE_RD_STEP , tune_roll_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
case PITCH :
updating_rate_d_down ( tune_pitch_rd , min_d , AUTOTUNE_RD_STEP , tune_pitch_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
case YAW :
updating_rate_d_down ( tune_yaw_rLPF , AUTOTUNE_RLPF_MIN , AUTOTUNE_RD_STEP , tune_yaw_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
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case YAW_D :
updating_rate_d_down ( tune_yaw_rd , min_d , AUTOTUNE_RD_STEP , tune_yaw_rp , AUTOTUNE_RP_MIN , AUTOTUNE_RP_MAX , AUTOTUNE_RP_STEP , target_rate , test_rate_min , test_rate_max ) ;
break ;
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}
}
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// update gains for the angle p up tune type
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void AC_AutoTune_Multi : : updating_angle_p_up_all ( AxisType test_axis )
{
switch ( test_axis ) {
case ROLL :
updating_angle_p_up ( tune_roll_sp , AUTOTUNE_SP_MAX , AUTOTUNE_SP_STEP , target_angle , test_angle_max , test_rate_min , test_rate_max ) ;
break ;
case PITCH :
updating_angle_p_up ( tune_pitch_sp , AUTOTUNE_SP_MAX , AUTOTUNE_SP_STEP , target_angle , test_angle_max , test_rate_min , test_rate_max ) ;
break ;
case YAW :
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case YAW_D :
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updating_angle_p_up ( tune_yaw_sp , AUTOTUNE_SP_MAX , AUTOTUNE_SP_STEP , target_angle , test_angle_max , test_rate_min , test_rate_max ) ;
break ;
}
}
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// update gains for the angle p down tune type
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void AC_AutoTune_Multi : : updating_angle_p_down_all ( AxisType test_axis )
{
switch ( test_axis ) {
case ROLL :
updating_angle_p_down ( tune_roll_sp , AUTOTUNE_SP_MIN , AUTOTUNE_SP_STEP , target_angle , test_angle_max , test_rate_min , test_rate_max ) ;
break ;
case PITCH :
updating_angle_p_down ( tune_pitch_sp , AUTOTUNE_SP_MIN , AUTOTUNE_SP_STEP , target_angle , test_angle_max , test_rate_min , test_rate_max ) ;
break ;
case YAW :
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case YAW_D :
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updating_angle_p_down ( tune_yaw_sp , AUTOTUNE_SP_MIN , AUTOTUNE_SP_STEP , target_angle , test_angle_max , test_rate_min , test_rate_max ) ;
break ;
}
}
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// set gains post tune for the tune type
void AC_AutoTune_Multi : : set_gains_post_tune ( AxisType test_axis )
{
switch ( tune_type ) {
case RD_UP :
break ;
case RD_DOWN :
switch ( test_axis ) {
case ROLL :
tune_roll_rd = MAX ( min_d , tune_roll_rd * AUTOTUNE_RD_BACKOFF ) ;
tune_roll_rp = MAX ( AUTOTUNE_RP_MIN , tune_roll_rp * AUTOTUNE_RD_BACKOFF ) ;
break ;
case PITCH :
tune_pitch_rd = MAX ( min_d , tune_pitch_rd * AUTOTUNE_RD_BACKOFF ) ;
tune_pitch_rp = MAX ( AUTOTUNE_RP_MIN , tune_pitch_rp * AUTOTUNE_RD_BACKOFF ) ;
break ;
case YAW :
tune_yaw_rLPF = MAX ( AUTOTUNE_RLPF_MIN , tune_yaw_rLPF * AUTOTUNE_RD_BACKOFF ) ;
tune_yaw_rp = MAX ( AUTOTUNE_RP_MIN , tune_yaw_rp * AUTOTUNE_RD_BACKOFF ) ;
break ;
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case YAW_D :
tune_yaw_rd = MAX ( min_d , tune_yaw_rd * AUTOTUNE_RD_BACKOFF ) ;
tune_yaw_rp = MAX ( AUTOTUNE_RP_MIN , tune_yaw_rp * AUTOTUNE_RD_BACKOFF ) ;
break ;
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}
break ;
case RP_UP :
switch ( test_axis ) {
case ROLL :
tune_roll_rp = MAX ( AUTOTUNE_RP_MIN , tune_roll_rp * AUTOTUNE_RP_BACKOFF ) ;
break ;
case PITCH :
tune_pitch_rp = MAX ( AUTOTUNE_RP_MIN , tune_pitch_rp * AUTOTUNE_RP_BACKOFF ) ;
break ;
case YAW :
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case YAW_D :
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tune_yaw_rp = MAX ( AUTOTUNE_RP_MIN , tune_yaw_rp * AUTOTUNE_RP_BACKOFF ) ;
break ;
}
break ;
case SP_DOWN :
break ;
case SP_UP :
switch ( test_axis ) {
case ROLL :
tune_roll_sp = MAX ( AUTOTUNE_SP_MIN , tune_roll_sp * AUTOTUNE_SP_BACKOFF ) ;
tune_roll_accel = MAX ( AUTOTUNE_RP_ACCEL_MIN , test_accel_max * AUTOTUNE_ACCEL_RP_BACKOFF ) ;
break ;
case PITCH :
tune_pitch_sp = MAX ( AUTOTUNE_SP_MIN , tune_pitch_sp * AUTOTUNE_SP_BACKOFF ) ;
tune_pitch_accel = MAX ( AUTOTUNE_RP_ACCEL_MIN , test_accel_max * AUTOTUNE_ACCEL_RP_BACKOFF ) ;
break ;
case YAW :
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case YAW_D :
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tune_yaw_sp = MAX ( AUTOTUNE_SP_MIN , tune_yaw_sp * AUTOTUNE_SP_BACKOFF ) ;
tune_yaw_accel = MAX ( AUTOTUNE_Y_ACCEL_MIN , test_accel_max * AUTOTUNE_ACCEL_Y_BACKOFF ) ;
break ;
}
break ;
case RFF_UP :
case MAX_GAINS :
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case TUNE_CHECK :
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// this should never happen
INTERNAL_ERROR ( AP_InternalError : : error_t : : flow_of_control ) ;
break ;
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case TUNE_COMPLETE :
break ;
}
}
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// updating_rate_d_up - increase D and adjust P to optimize the D term for a little bounce back
// optimize D term while keeping the maximum just below the target by adjusting P
void AC_AutoTune_Multi : : updating_rate_d_up ( float & tune_d , float tune_d_min , float tune_d_max , float tune_d_step_ratio , float & tune_p , float tune_p_min , float tune_p_max , float tune_p_step_ratio , float rate_target , float meas_rate_min , float meas_rate_max )
{
if ( meas_rate_max > rate_target ) {
// if maximum measurement was higher than target
// reduce P gain (which should reduce maximum)
tune_p - = tune_p * tune_p_step_ratio ;
if ( tune_p < tune_p_min ) {
// P gain is at minimum so start reducing D
tune_p = tune_p_min ;
tune_d - = tune_d * tune_d_step_ratio ;
if ( tune_d < = tune_d_min ) {
// We have reached minimum D gain so stop tuning
tune_d = tune_d_min ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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// This may be mean AGGR should be increased or MIN_D decreased
gcs ( ) . send_text ( MAV_SEVERITY_INFO , " AutoTune: Min Rate D limit reached " ) ;
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}
}
} else if ( ( meas_rate_max < rate_target * ( 1.0f - AUTOTUNE_D_UP_DOWN_MARGIN ) ) & & ( tune_p < = tune_p_max ) ) {
// we have not achieved a high enough maximum to get a good measurement of bounce back.
// increase P gain (which should increase maximum)
tune_p + = tune_p * tune_p_step_ratio ;
if ( tune_p > = tune_p_max ) {
tune_p = tune_p_max ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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}
} else {
// we have a good measurement of bounce back
if ( meas_rate_max - meas_rate_min > meas_rate_max * aggressiveness ) {
// ignore the next result unless it is the same as this one
ignore_next = true ;
// bounce back is bigger than our threshold so increment the success counter
counter + + ;
} else {
if ( ignore_next = = false ) {
// bounce back is smaller than our threshold so decrement the success counter
if ( counter > 0 ) {
counter - - ;
}
// increase D gain (which should increase bounce back)
tune_d + = tune_d * tune_d_step_ratio * 2.0f ;
// stop tuning if we hit maximum D
if ( tune_d > = tune_d_max ) {
tune_d = tune_d_max ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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}
} else {
ignore_next = false ;
}
}
}
}
// updating_rate_d_down - decrease D and adjust P to optimize the D term for no bounce back
// optimize D term while keeping the maximum just below the target by adjusting P
void AC_AutoTune_Multi : : updating_rate_d_down ( float & tune_d , float tune_d_min , float tune_d_step_ratio , float & tune_p , float tune_p_min , float tune_p_max , float tune_p_step_ratio , float rate_target , float meas_rate_min , float meas_rate_max )
{
if ( meas_rate_max > rate_target ) {
// if maximum measurement was higher than target
// reduce P gain (which should reduce maximum)
tune_p - = tune_p * tune_p_step_ratio ;
if ( tune_p < tune_p_min ) {
// P gain is at minimum so start reducing D gain
tune_p = tune_p_min ;
tune_d - = tune_d * tune_d_step_ratio ;
if ( tune_d < = tune_d_min ) {
// We have reached minimum D so stop tuning
tune_d = tune_d_min ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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// This may be mean AGGR should be increased or MIN_D decreased
gcs ( ) . send_text ( MAV_SEVERITY_INFO , " AutoTune: Min Rate D limit reached " ) ;
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}
}
} else if ( ( meas_rate_max < rate_target * ( 1.0f - AUTOTUNE_D_UP_DOWN_MARGIN ) ) & & ( tune_p < = tune_p_max ) ) {
// we have not achieved a high enough maximum to get a good measurement of bounce back.
// increase P gain (which should increase maximum)
tune_p + = tune_p * tune_p_step_ratio ;
if ( tune_p > = tune_p_max ) {
tune_p = tune_p_max ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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}
} else {
// we have a good measurement of bounce back
if ( meas_rate_max - meas_rate_min < meas_rate_max * aggressiveness ) {
if ( ignore_next = = false ) {
// bounce back is less than our threshold so increment the success counter
counter + + ;
} else {
ignore_next = false ;
}
} else {
// ignore the next result unless it is the same as this one
ignore_next = true ;
// bounce back is larger than our threshold so decrement the success counter
if ( counter > 0 ) {
counter - - ;
}
// decrease D gain (which should decrease bounce back)
tune_d - = tune_d * tune_d_step_ratio ;
// stop tuning if we hit minimum D
if ( tune_d < = tune_d_min ) {
tune_d = tune_d_min ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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// This may be mean AGGR should be increased or MIN_D decreased
gcs ( ) . send_text ( MAV_SEVERITY_INFO , " AutoTune: Min Rate D limit reached " ) ;
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}
}
}
}
// updating_rate_p_up_d_down - increase P to ensure the target is reached while checking bounce back isn't increasing
// P is increased until we achieve our target within a reasonable time while reducing D if bounce back increases above the threshold
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void AC_AutoTune_Multi : : updating_rate_p_up_d_down ( float & tune_d , float tune_d_min , float tune_d_step_ratio , float & tune_p , float tune_p_min , float tune_p_max , float tune_p_step_ratio , float rate_target , float meas_rate_min , float meas_rate_max , bool fail_min_d )
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{
if ( meas_rate_max > rate_target * ( 1 + 0.5f * aggressiveness ) ) {
// ignore the next result unless it is the same as this one
ignore_next = true ;
// if maximum measurement was greater than target so increment the success counter
counter + + ;
} else if ( ( meas_rate_max < rate_target ) & & ( meas_rate_max > rate_target * ( 1.0f - AUTOTUNE_D_UP_DOWN_MARGIN ) ) & & ( meas_rate_max - meas_rate_min > meas_rate_max * aggressiveness ) & & ( tune_d > tune_d_min ) ) {
// if bounce back was larger than the threshold so decrement the success counter
if ( counter > 0 ) {
counter - - ;
}
// decrease D gain (which should decrease bounce back)
tune_d - = tune_d * tune_d_step_ratio ;
// do not decrease the D term past the minimum
if ( tune_d < = tune_d_min ) {
tune_d = tune_d_min ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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if ( fail_min_d ) {
gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " AutoTune: Rate D Gain Determination Failed " ) ;
mode = FAILED ;
LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_FAILED ) ;
}
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}
// decrease P gain to match D gain reduction
tune_p - = tune_p * tune_p_step_ratio ;
// do not decrease the P term past the minimum
if ( tune_p < = tune_p_min ) {
tune_p = tune_p_min ;
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gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " AutoTune: Rate P Gain Determination Failed " ) ;
mode = FAILED ;
LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_FAILED ) ;
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}
} else {
if ( ignore_next = = false ) {
// if maximum measurement was lower than target so decrement the success counter
if ( counter > 0 ) {
counter - - ;
}
// increase P gain (which should increase the maximum)
tune_p + = tune_p * tune_p_step_ratio ;
// stop tuning if we hit maximum P
if ( tune_p > = tune_p_max ) {
tune_p = tune_p_max ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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}
} else {
ignore_next = false ;
}
}
}
// updating_angle_p_down - decrease P until we don't reach the target before time out
// P is decreased to ensure we are not overshooting the target
void AC_AutoTune_Multi : : updating_angle_p_down ( float & tune_p , float tune_p_min , float tune_p_step_ratio , float angle_target , float meas_angle_max , float meas_rate_min , float meas_rate_max )
{
if ( meas_angle_max < angle_target * ( 1 + 0.5f * aggressiveness ) ) {
if ( ignore_next = = false ) {
// if maximum measurement was lower than target so increment the success counter
counter + + ;
} else {
ignore_next = false ;
}
} else {
// ignore the next result unless it is the same as this one
ignore_next = true ;
// if maximum measurement was higher than target so decrement the success counter
if ( counter > 0 ) {
counter - - ;
}
// decrease P gain (which should decrease the maximum)
tune_p - = tune_p * tune_p_step_ratio ;
// stop tuning if we hit maximum P
if ( tune_p < = tune_p_min ) {
tune_p = tune_p_min ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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gcs ( ) . send_text ( MAV_SEVERITY_CRITICAL , " AutoTune: Angle P Gain Determination Failed " ) ;
mode = FAILED ;
LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_FAILED ) ;
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}
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}
}
// updating_angle_p_up - increase P to ensure the target is reached
// P is increased until we achieve our target within a reasonable time
void AC_AutoTune_Multi : : updating_angle_p_up ( float & tune_p , float tune_p_max , float tune_p_step_ratio , float angle_target , float meas_angle_max , float meas_rate_min , float meas_rate_max )
{
if ( ( meas_angle_max > angle_target * ( 1 + 0.5f * aggressiveness ) ) | |
( ( meas_angle_max > angle_target ) & & ( meas_rate_min < - meas_rate_max * aggressiveness ) ) ) {
// ignore the next result unless it is the same as this one
ignore_next = true ;
// if maximum measurement was greater than target so increment the success counter
counter + + ;
} else {
if ( ignore_next = = false ) {
// if maximum measurement was lower than target so decrement the success counter
if ( counter > 0 ) {
counter - - ;
}
// increase P gain (which should increase the maximum)
tune_p + = tune_p * tune_p_step_ratio ;
// stop tuning if we hit maximum P
if ( tune_p > = tune_p_max ) {
tune_p = tune_p_max ;
counter = AUTOTUNE_SUCCESS_COUNT ;
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LOGGER_WRITE_EVENT ( LogEvent : : AUTOTUNE_REACHED_LIMIT ) ;
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}
} else {
ignore_next = false ;
}
}
}
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# if HAL_LOGGING_ENABLED
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void AC_AutoTune_Multi : : Log_AutoTune ( )
{
if ( ( tune_type = = SP_DOWN ) | | ( tune_type = = SP_UP ) ) {
switch ( axis ) {
case ROLL :
Log_Write_AutoTune ( axis , tune_type , target_angle , test_angle_min , test_angle_max , tune_roll_rp , tune_roll_rd , tune_roll_sp , test_accel_max ) ;
break ;
case PITCH :
Log_Write_AutoTune ( axis , tune_type , target_angle , test_angle_min , test_angle_max , tune_pitch_rp , tune_pitch_rd , tune_pitch_sp , test_accel_max ) ;
break ;
case YAW :
Log_Write_AutoTune ( axis , tune_type , target_angle , test_angle_min , test_angle_max , tune_yaw_rp , tune_yaw_rLPF , tune_yaw_sp , test_accel_max ) ;
break ;
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case YAW_D :
Log_Write_AutoTune ( axis , tune_type , target_angle , test_angle_min , test_angle_max , tune_yaw_rp , tune_yaw_rd , tune_yaw_sp , test_accel_max ) ;
break ;
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}
} else {
switch ( axis ) {
case ROLL :
Log_Write_AutoTune ( axis , tune_type , target_rate , test_rate_min , test_rate_max , tune_roll_rp , tune_roll_rd , tune_roll_sp , test_accel_max ) ;
break ;
case PITCH :
Log_Write_AutoTune ( axis , tune_type , target_rate , test_rate_min , test_rate_max , tune_pitch_rp , tune_pitch_rd , tune_pitch_sp , test_accel_max ) ;
break ;
case YAW :
Log_Write_AutoTune ( axis , tune_type , target_rate , test_rate_min , test_rate_max , tune_yaw_rp , tune_yaw_rLPF , tune_yaw_sp , test_accel_max ) ;
break ;
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case YAW_D :
Log_Write_AutoTune ( axis , tune_type , target_rate , test_rate_min , test_rate_max , tune_yaw_rp , tune_yaw_rd , tune_yaw_sp , test_accel_max ) ;
break ;
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}
}
}
void AC_AutoTune_Multi : : Log_AutoTuneDetails ( )
{
Log_Write_AutoTuneDetails ( lean_angle , rotation_rate ) ;
}
// @LoggerMessage: ATUN
// @Description: Copter/QuadPlane AutoTune
// @Vehicles: Copter, Plane
// @Field: TimeUS: Time since system startup
// @Field: Axis: which axis is currently being tuned
// @Field: TuneStep: step in autotune process
// @Field: Targ: target angle or rate, depending on tuning step
// @Field: Min: measured minimum target angle or rate
// @Field: Max: measured maximum target angle or rate
// @Field: RP: new rate gain P term
// @Field: RD: new rate gain D term
// @Field: SP: new angle P term
// @Field: ddt: maximum measured twitching acceleration
// Write an Autotune data packet
void AC_AutoTune_Multi : : Log_Write_AutoTune ( uint8_t _axis , uint8_t tune_step , float meas_target , float meas_min , float meas_max , float new_gain_rp , float new_gain_rd , float new_gain_sp , float new_ddt )
{
AP : : logger ( ) . Write (
" ATUN " ,
" TimeUS,Axis,TuneStep,Targ,Min,Max,RP,RD,SP,ddt " ,
" s--ddd---o " ,
" F--000---0 " ,
" QBBfffffff " ,
AP_HAL : : micros64 ( ) ,
axis ,
tune_step ,
meas_target * 0.01f ,
meas_min * 0.01f ,
meas_max * 0.01f ,
new_gain_rp ,
new_gain_rd ,
new_gain_sp ,
new_ddt ) ;
}
// Write an Autotune data packet
void AC_AutoTune_Multi : : Log_Write_AutoTuneDetails ( float angle_cd , float rate_cds )
{
// @LoggerMessage: ATDE
// @Description: AutoTune data packet
// @Field: TimeUS: Time since system startup
// @Field: Angle: current angle
// @Field: Rate: current angular rate
AP : : logger ( ) . WriteStreaming (
" ATDE " ,
" TimeUS,Angle,Rate " ,
" sdk " ,
" F00 " ,
" Qff " ,
AP_HAL : : micros64 ( ) ,
angle_cd * 0.01f ,
rate_cds * 0.01f ) ;
}
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# endif // HAL_LOGGING_ENABLED
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float AC_AutoTune_Multi : : target_angle_max_rp_cd ( ) const
{
return attitude_control - > lean_angle_max_cd ( ) * AUTOTUNE_TARGET_ANGLE_MAX_RP_SCALE ;
}
float AC_AutoTune_Multi : : target_angle_max_y_cd ( ) const
{
// Aircraft with small lean angle will generally benefit from proportional smaller yaw twitch size
return attitude_control - > lean_angle_max_cd ( ) * AUTOTUNE_TARGET_ANGLE_MAX_Y_SCALE ;
}
float AC_AutoTune_Multi : : target_angle_min_rp_cd ( ) const
{
return attitude_control - > lean_angle_max_cd ( ) * AUTOTUNE_TARGET_ANGLE_MIN_RP_SCALE ;
}
float AC_AutoTune_Multi : : target_angle_min_y_cd ( ) const
{
// Aircraft with small lean angle will generally benefit from proportional smaller yaw twitch size
return attitude_control - > lean_angle_max_cd ( ) * AUTOTUNE_TARGET_ANGLE_MIN_Y_SCALE ;
}
float AC_AutoTune_Multi : : angle_lim_max_rp_cd ( ) const
{
return attitude_control - > lean_angle_max_cd ( ) * AUTOTUNE_ANGLE_ABORT_RP_SCALE ;
}
float AC_AutoTune_Multi : : angle_lim_neg_rpy_cd ( ) const
{
return attitude_control - > lean_angle_max_cd ( ) * AUTOTUNE_ANGLE_NEG_RP_SCALE ;
}
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void AC_AutoTune_Multi : : twitch_test_init ( )
{
float target_max_rate ;
switch ( axis ) {
case ROLL : {
target_max_rate = MAX ( AUTOTUNE_TARGET_MIN_RATE_RLLPIT_CDS , step_scaler * AUTOTUNE_TARGET_RATE_RLLPIT_CDS ) ;
target_rate = constrain_float ( ToDeg ( attitude_control - > max_rate_step_bf_roll ( ) ) * 100.0f , AUTOTUNE_TARGET_MIN_RATE_RLLPIT_CDS , target_max_rate ) ;
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target_angle = constrain_float ( ToDeg ( attitude_control - > max_angle_step_bf_roll ( ) ) * 100.0f , target_angle_min_rp_cd ( ) , target_angle_max_rp_cd ( ) ) ;
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rotation_rate_filt . set_cutoff_frequency ( attitude_control - > get_rate_roll_pid ( ) . filt_D_hz ( ) * 2.0f ) ;
break ;
}
case PITCH : {
target_max_rate = MAX ( AUTOTUNE_TARGET_MIN_RATE_RLLPIT_CDS , step_scaler * AUTOTUNE_TARGET_RATE_RLLPIT_CDS ) ;
target_rate = constrain_float ( ToDeg ( attitude_control - > max_rate_step_bf_pitch ( ) ) * 100.0f , AUTOTUNE_TARGET_MIN_RATE_RLLPIT_CDS , target_max_rate ) ;
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target_angle = constrain_float ( ToDeg ( attitude_control - > max_angle_step_bf_pitch ( ) ) * 100.0f , target_angle_min_rp_cd ( ) , target_angle_max_rp_cd ( ) ) ;
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rotation_rate_filt . set_cutoff_frequency ( attitude_control - > get_rate_pitch_pid ( ) . filt_D_hz ( ) * 2.0f ) ;
break ;
}
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case YAW :
case YAW_D : {
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target_max_rate = MAX ( AUTOTUNE_TARGET_MIN_RATE_YAW_CDS , step_scaler * AUTOTUNE_TARGET_RATE_YAW_CDS ) ;
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target_rate = constrain_float ( ToDeg ( attitude_control - > max_rate_step_bf_yaw ( ) * 0.75f ) * 100.0f , AUTOTUNE_TARGET_MIN_RATE_YAW_CDS , target_max_rate ) ;
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target_angle = constrain_float ( ToDeg ( attitude_control - > max_angle_step_bf_yaw ( ) * 0.75f ) * 100.0f , target_angle_min_y_cd ( ) , target_angle_max_y_cd ( ) ) ;
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if ( axis = = YAW_D ) {
rotation_rate_filt . set_cutoff_frequency ( attitude_control - > get_rate_yaw_pid ( ) . filt_D_hz ( ) * 2.0f ) ;
} else {
rotation_rate_filt . set_cutoff_frequency ( AUTOTUNE_Y_FILT_FREQ ) ;
}
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break ;
}
}
if ( ( tune_type = = SP_DOWN ) | | ( tune_type = = SP_UP ) ) {
rotation_rate_filt . reset ( start_rate ) ;
} else {
rotation_rate_filt . reset ( 0 ) ;
}
}
//run twitch test
void AC_AutoTune_Multi : : twitch_test_run ( AxisType test_axis , const float dir_sign )
{
// disable rate limits
attitude_control - > use_sqrt_controller ( false ) ;
// hold current attitude
if ( ( tune_type = = SP_DOWN ) | | ( tune_type = = SP_UP ) ) {
// step angle targets on first iteration
if ( twitch_first_iter ) {
twitch_first_iter = false ;
// Testing increasing stabilize P gain so will set lean angle target
switch ( test_axis ) {
case ROLL :
// request roll to 20deg
attitude_control - > input_angle_step_bf_roll_pitch_yaw ( dir_sign * target_angle , 0.0f , 0.0f ) ;
break ;
case PITCH :
// request pitch to 20deg
attitude_control - > input_angle_step_bf_roll_pitch_yaw ( 0.0f , dir_sign * target_angle , 0.0f ) ;
break ;
case YAW :
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case YAW_D :
// request yaw to 20deg
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attitude_control - > input_angle_step_bf_roll_pitch_yaw ( 0.0f , 0.0f , dir_sign * target_angle ) ;
break ;
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}
} else {
attitude_control - > input_rate_bf_roll_pitch_yaw ( 0.0f , 0.0f , 0.0f ) ;
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}
} else {
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attitude_control - > input_rate_bf_roll_pitch_yaw_2 ( 0.0f , 0.0f , 0.0f ) ;
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// Testing rate P and D gains so will set body-frame rate targets.
// Rate controller will use existing body-frame rates and convert to motor outputs
// for all axes except the one we override here.
switch ( test_axis ) {
case ROLL :
// override body-frame roll rate
attitude_control - > rate_bf_roll_target ( dir_sign * target_rate + start_rate ) ;
break ;
case PITCH :
// override body-frame pitch rate
attitude_control - > rate_bf_pitch_target ( dir_sign * target_rate + start_rate ) ;
break ;
case YAW :
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case YAW_D :
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// override body-frame yaw rate
attitude_control - > rate_bf_yaw_target ( dir_sign * target_rate + start_rate ) ;
break ;
}
}
// capture this iteration's rotation rate and lean angle
float gyro_reading = 0 ;
switch ( test_axis ) {
case ROLL :
gyro_reading = ahrs_view - > get_gyro ( ) . x ;
lean_angle = dir_sign * ( ahrs_view - > roll_sensor - ( int32_t ) start_angle ) ;
break ;
case PITCH :
gyro_reading = ahrs_view - > get_gyro ( ) . y ;
lean_angle = dir_sign * ( ahrs_view - > pitch_sensor - ( int32_t ) start_angle ) ;
break ;
case YAW :
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case YAW_D :
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gyro_reading = ahrs_view - > get_gyro ( ) . z ;
lean_angle = dir_sign * wrap_180_cd ( ahrs_view - > yaw_sensor - ( int32_t ) start_angle ) ;
break ;
}
// Add filter to measurements
float filter_value ;
switch ( tune_type ) {
case SP_DOWN :
case SP_UP :
filter_value = dir_sign * ( ToDeg ( gyro_reading ) * 100.0f ) ;
break ;
default :
filter_value = dir_sign * ( ToDeg ( gyro_reading ) * 100.0f - start_rate ) ;
break ;
}
rotation_rate = rotation_rate_filt . apply ( filter_value ,
AP : : scheduler ( ) . get_loop_period_s ( ) ) ;
switch ( tune_type ) {
case RD_UP :
case RD_DOWN :
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twitching_test_rate ( lean_angle , rotation_rate , target_rate , test_rate_min , test_rate_max , test_angle_min ) ;
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twitching_measure_acceleration ( test_accel_max , rotation_rate , rate_max ) ;
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twitching_abort_rate ( lean_angle , rotation_rate , angle_finish , test_rate_min , test_angle_min ) ;
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break ;
case RP_UP :
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twitching_test_rate ( lean_angle , rotation_rate , target_rate * ( 1 + 0.5f * aggressiveness ) , test_rate_min , test_rate_max , test_angle_min ) ;
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twitching_measure_acceleration ( test_accel_max , rotation_rate , rate_max ) ;
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twitching_abort_rate ( lean_angle , rotation_rate , angle_finish , test_rate_min , test_angle_min ) ;
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break ;
case SP_DOWN :
case SP_UP :
twitching_test_angle ( lean_angle , rotation_rate , target_angle * ( 1 + 0.5f * aggressiveness ) , test_angle_min , test_angle_max , test_rate_min , test_rate_max ) ;
twitching_measure_acceleration ( test_accel_max , rotation_rate - dir_sign * start_rate , rate_max ) ;
break ;
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case RFF_UP :
case MAX_GAINS :
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case TUNE_CHECK :
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// this should never happen
INTERNAL_ERROR ( AP_InternalError : : error_t : : flow_of_control ) ;
break ;
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default :
break ;
}
}
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// get_testing_step_timeout_ms accessor
uint32_t AC_AutoTune_Multi : : get_testing_step_timeout_ms ( ) const
{
return AUTOTUNE_TESTING_STEP_TIMEOUT_MS ;
}
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# endif // AC_AUTOTUNE_ENABLED