/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* support for autotune of multirotors. Based on original autotune code from ArduCopter, written by Leonard Hall Converted to a library by Andrew Tridgell */ #pragma once #include "AC_AutoTune_config.h" #if AC_AUTOTUNE_ENABLED #include #include #include #include "AC_AutoTune_FreqResp.h" #define AUTOTUNE_AXIS_BITMASK_ROLL 1 #define AUTOTUNE_AXIS_BITMASK_PITCH 2 #define AUTOTUNE_AXIS_BITMASK_YAW 4 #define AUTOTUNE_AXIS_BITMASK_YAW_D 8 #define AUTOTUNE_SUCCESS_COUNT 4 // The number of successful iterations we need to freeze at current gains // Auto Tune message ids for ground station #define AUTOTUNE_MESSAGE_STARTED 0 #define AUTOTUNE_MESSAGE_STOPPED 1 #define AUTOTUNE_MESSAGE_SUCCESS 2 #define AUTOTUNE_MESSAGE_FAILED 3 #define AUTOTUNE_MESSAGE_SAVED_GAINS 4 #define AUTOTUNE_MESSAGE_TESTING 5 #define AUTOTUNE_ANNOUNCE_INTERVAL_MS 2000 #define AUTOTUNE_TARGET_MIN_ANGLE_RLLPIT_CD 1000 // minimum target angle during TESTING_RATE step that will cause us to move to next step #define AUTOTUNE_TARGET_ANGLE_RLLPIT_CD 2000 // target angle during TESTING_RATE step that will cause us to move to next step #define AUTOTUNE_TARGET_ANGLE_YAW_CD 3000 // target angle during TESTING_RATE step that will cause us to move to next step class AC_AutoTune { public: // constructor AC_AutoTune(); // main run loop virtual void run(); // save gained, called on disarm virtual void save_tuning_gains() = 0; // stop tune, reverting gains void stop(); // reset Autotune so that gains are not saved again and autotune can be run again. void reset() { mode = UNINITIALISED; axes_completed = 0; } protected: // axis that can be tuned enum AxisType { ROLL = 0, // roll axis is being tuned (either angle or rate) PITCH = 1, // pitch axis is being tuned (either angle or rate) YAW = 2, // yaw axis is being tuned using FLTE (either angle or rate) YAW_D = 3, // yaw axis is being tuned using D (either angle or rate) }; // // methods that must be supplied by the vehicle specific subclass // virtual bool init(void) = 0; // get pilot input for desired climb rate virtual float get_pilot_desired_climb_rate_cms(void) const = 0; // get pilot input for designed roll and pitch, and yaw rate virtual void get_pilot_desired_rp_yrate_cd(float &roll_cd, float &pitch_cd, float &yaw_rate_cds) = 0; // init pos controller Z velocity and accel limits virtual void init_z_limits() = 0; #if HAL_LOGGING_ENABLED // log PIDs at full rate for during twitch virtual void log_pids() = 0; #endif // // methods to load and save gains // // backup original gains and prepare for start of tuning virtual void backup_gains_and_initialise(); // switch to use original gains virtual void load_orig_gains() = 0; // switch to gains found by last successful autotune virtual void load_tuned_gains() = 0; // load gains used between tests. called during testing mode's update-gains step to set gains ahead of return-to-level step virtual void load_intra_test_gains() = 0; // load gains for next test. relies on axis variable being set virtual void load_test_gains() = 0; // reset the test vaariables for each vehicle virtual void reset_vehicle_test_variables() = 0; // reset the update gain variables for each vehicle virtual void reset_update_gain_variables() = 0; // test initialization and run methods that should be overridden for each vehicle virtual void test_init() = 0; virtual void test_run(AxisType test_axis, const float dir_sign) = 0; // return true if user has enabled autotune for roll, pitch or yaw axis bool roll_enabled() const; bool pitch_enabled() const; bool yaw_enabled() const; bool yaw_d_enabled() const; // update gains for the rate p up tune type virtual void updating_rate_p_up_all(AxisType test_axis)=0; // update gains for the rate d up tune type virtual void updating_rate_d_up_all(AxisType test_axis)=0; // update gains for the rate d down tune type virtual void updating_rate_d_down_all(AxisType test_axis)=0; // update gains for the angle p up tune type virtual void updating_angle_p_up_all(AxisType test_axis)=0; // update gains for the angle p down tune type virtual void updating_angle_p_down_all(AxisType test_axis)=0; // set gains post tune for the tune type virtual void set_gains_post_tune(AxisType test_axis)=0; // reverse direction for twitch test virtual bool twitch_reverse_direction() = 0; #if HAL_LOGGING_ENABLED virtual void Log_AutoTune() = 0; virtual void Log_AutoTuneDetails() = 0; virtual void Log_AutoTuneSweep() = 0; #endif // internal init function, should be called from init() bool init_internals(bool use_poshold, AC_AttitudeControl *attitude_control, AC_PosControl *pos_control, AP_AHRS_View *ahrs_view, AP_InertialNav *inertial_nav); // send intermittent updates to user on status of tune virtual void do_gcs_announcements() = 0; // send post test updates to user virtual void do_post_test_gcs_announcements() = 0; // send message with high level status (e.g. Started, Stopped) void update_gcs(uint8_t message_id) const; // send lower level step status (e.g. Pilot overrides Active) void send_step_string(); // convert tune type to string for reporting const char *type_string() const; // return current axis string const char *axis_string() const; // report final gains for a given axis to GCS virtual void report_final_gains(AxisType test_axis) const = 0; // Functions added for heli autotune // Add additional updating gain functions specific to heli // generic method used by subclasses to update gains for the rate ff up tune type virtual void updating_rate_ff_up_all(AxisType test_axis)=0; // generic method used by subclasses to update gains for the max gain tune type virtual void updating_max_gains_all(AxisType test_axis)=0; // steps performed while in the tuning mode enum StepType { WAITING_FOR_LEVEL = 0, // autotune is waiting for vehicle to return to level before beginning the next twitch TESTING = 1, // autotune has begun a test and is watching the resulting vehicle movement UPDATE_GAINS = 2 // autotune has completed a test and is updating the gains based on the results }; // mini steps performed while in Tuning mode, Testing step enum TuneType { RD_UP = 0, // rate D is being tuned up RD_DOWN = 1, // rate D is being tuned down RP_UP = 2, // rate P is being tuned up RFF_UP = 3, // rate FF is being tuned up SP_UP = 4, // angle P is being tuned up SP_DOWN = 5, // angle P is being tuned down MAX_GAINS = 6, // max allowable stable gains are determined TUNE_CHECK = 7, // frequency sweep with tuned gains TUNE_COMPLETE = 8 // Reached end of tuning }; TuneType tune_seq[6]; // holds sequence of tune_types to be performed uint8_t tune_seq_curr; // current tune sequence step // get the next tune type void next_tune_type(TuneType &curr_tune_type, bool reset); // Sets customizable tune sequence for the vehicle virtual void set_tune_sequence() = 0; // get_axis_bitmask accessor virtual uint8_t get_axis_bitmask() const = 0; // get_testing_step_timeout_ms accessor virtual uint32_t get_testing_step_timeout_ms() const = 0; // get attitude for slow position hold in autotune mode void get_poshold_attitude(float &roll_cd, float &pitch_cd, float &yaw_cd); // type of gains to load enum GainType { GAIN_ORIGINAL = 0, GAIN_TEST = 1, GAIN_INTRA_TEST = 2, GAIN_TUNED = 3, }; void load_gains(enum GainType gain_type); // autotune modes (high level states) enum TuneMode { UNINITIALISED = 0, // autotune has never been run TUNING = 1, // autotune is testing gains SUCCESS = 2, // tuning has completed, user is flight testing the new gains FAILED = 3, // tuning has failed, user is flying on original gains }; TuneMode mode; // see TuneMode for what modes are allowed // copies of object pointers to make code a bit clearer AC_AttitudeControl *attitude_control; AC_PosControl *pos_control; AP_AHRS_View *ahrs_view; AP_InertialNav *inertial_nav; AP_Motors *motors; AxisType axis; // current axis being tuned. see AxisType enum bool positive_direction; // false = tuning in negative direction (i.e. left for roll), true = positive direction (i.e. right for roll) StepType step; // see StepType for what steps are performed TuneType tune_type; // see TuneType bool ignore_next; // true = ignore the next test bool twitch_first_iter; // true on first iteration of a twitch (used to signal we must step the attitude or rate target) uint8_t axes_completed; // bitmask of completed axes float test_rate_min; // the minimum angular rate achieved during TESTING_RATE step-multi only float test_rate_max; // the maximum angular rate achieved during TESTING_RATE step-multi only float test_angle_min; // the minimum angle achieved during TESTING_ANGLE step-multi only float test_angle_max; // the maximum angle achieved during TESTING_ANGLE step-multi only uint32_t step_start_time_ms; // start time of current tuning step (used for timeout checks) uint32_t step_time_limit_ms; // time limit of current autotune process int8_t counter; // counter for tuning gains float target_rate; // target rate-multi only float target_angle; // target angle-multi only float start_rate; // start rate - parent and multi float start_angle; // start angle float rate_max; // maximum rate variable - parent and multi float test_accel_max; // maximum acceleration variable float step_scaler; // scaler to reduce maximum target step - parent and multi float abort_angle; // Angle that test is aborted- parent and multi float desired_yaw_cd; // yaw heading during tune - parent and Tradheli LowPassFilterFloat rotation_rate_filt; // filtered rotation rate in radians/second // backup of currently being tuned parameter values float orig_roll_rp, orig_roll_ri, orig_roll_rd, orig_roll_rff, orig_roll_fltt, orig_roll_smax, orig_roll_sp, orig_roll_accel; float orig_pitch_rp, orig_pitch_ri, orig_pitch_rd, orig_pitch_rff, orig_pitch_fltt, orig_pitch_smax, orig_pitch_sp, orig_pitch_accel; float orig_yaw_rp, orig_yaw_ri, orig_yaw_rd, orig_yaw_rff, orig_yaw_fltt, orig_yaw_smax, orig_yaw_rLPF, orig_yaw_sp, orig_yaw_accel; bool orig_bf_feedforward; // currently being tuned parameter values float tune_roll_rp, tune_roll_rd, tune_roll_sp, tune_roll_accel; float tune_pitch_rp, tune_pitch_rd, tune_pitch_sp, tune_pitch_accel; float tune_yaw_rp, tune_yaw_rLPF, tune_yaw_sp, tune_yaw_accel; float tune_roll_rff, tune_pitch_rff, tune_yaw_rd, tune_yaw_rff; uint32_t announce_time; float lean_angle; float rotation_rate; float roll_cd, pitch_cd; // heli specific variables uint8_t freq_cnt; // dwell test iteration counter float start_freq; //start freq for dwell test float stop_freq; //ending freq for dwell test bool ff_up_first_iter; // true on first iteration of ff up testing private: // return true if we have a good position estimate virtual bool position_ok(); // initialise position controller bool init_position_controller(); // main state machine to level vehicle, perform a test and update gains // directly updates attitude controller with targets void control_attitude(); // returns true if vehicle is close to level bool currently_level(); bool pilot_override; // true = pilot is overriding controls so we suspend tuning temporarily bool use_poshold; // true = enable position hold bool have_position; // true = start_position is value Vector3f start_position; // target when holding position as an offset from EKF origin in cm in NEU frame // variables uint32_t override_time; // the last time the pilot overrode the controls uint32_t level_start_time_ms; // start time of waiting for level uint32_t level_fail_warning_time_ms; // last time level failure warning message was sent to GCS // time in ms of last pilot override warning uint32_t last_pilot_override_warning; }; #endif // AC_AUTOTUNE_ENABLED