mirror of https://github.com/ArduPilot/ardupilot
AC_AutoTune: combine dwell_init methods
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@ -156,11 +156,11 @@ void AC_AutoTune_Heli::test_init()
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if (!is_equal(start_freq,stop_freq)) {
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// initialize determine_gain function whenever test is initialized
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freqresp_rate.init(AC_AutoTune_FreqResp::InputType::SWEEP, AC_AutoTune_FreqResp::ResponseType::RATE);
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dwell_test_init(start_freq, stop_freq);
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dwell_test_init(start_freq, stop_freq, RATE);
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} else {
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// initialize determine_gain function whenever test is initialized
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freqresp_rate.init(AC_AutoTune_FreqResp::InputType::DWELL, AC_AutoTune_FreqResp::ResponseType::RATE);
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dwell_test_init(start_freq, start_freq);
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dwell_test_init(start_freq, start_freq, RATE);
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}
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if (!is_zero(start_freq)) {
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// 4 seconds is added to allow aircraft to achieve start attitude. Then the time to conduct the dwells is added to it.
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@ -186,11 +186,11 @@ void AC_AutoTune_Heli::test_init()
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if (!is_equal(start_freq,stop_freq)) {
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// initialize determine gain function
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freqresp_angle.init(AC_AutoTune_FreqResp::InputType::SWEEP, AC_AutoTune_FreqResp::ResponseType::ANGLE);
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angle_dwell_test_init(start_freq, stop_freq);
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dwell_test_init(start_freq, stop_freq, ANGLE);
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} else {
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// initialize determine gain function
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freqresp_angle.init(AC_AutoTune_FreqResp::InputType::DWELL, AC_AutoTune_FreqResp::ResponseType::ANGLE);
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angle_dwell_test_init(start_freq, start_freq);
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dwell_test_init(start_freq, start_freq, ANGLE);
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}
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// TODO add time limit for sweep test
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@ -910,30 +910,61 @@ void AC_AutoTune_Heli::rate_ff_test_run(float max_angle_cd, float target_rate_cd
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}
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void AC_AutoTune_Heli::dwell_test_init(float start_frq, float filt_freq)
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void AC_AutoTune_Heli::dwell_test_init(float start_frq, float filt_freq, DwellType dwell_type)
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{
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rotation_rate_filt.reset(0);
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rotation_rate_filt.set_cutoff_frequency(filt_freq);
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command_filt.reset(0);
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command_filt.set_cutoff_frequency(filt_freq);
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target_rate_filt.reset(0);
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target_rate_filt.set_cutoff_frequency(filt_freq);
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filt_target_rate = 0.0f;
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dwell_start_time_ms = 0.0f;
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settle_time = 200;
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if (!is_equal(start_freq, stop_freq)) {
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reset_sweep_variables();
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curr_test.gain = 0.0f;
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curr_test.phase = 0.0f;
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rotation_rate_filt.set_cutoff_frequency(filt_freq);
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command_filt.set_cutoff_frequency(filt_freq);
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target_rate_filt.set_cutoff_frequency(filt_freq);
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if (dwell_type == RATE) {
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rotation_rate_filt.reset(0);
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command_filt.reset(0);
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target_rate_filt.reset(0);
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rotation_rate = 0.0f;
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command_out = 0.0f;
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filt_target_rate = 0.0f;
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} else {
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switch (axis) {
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case ROLL:
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rotation_rate_filt.reset(((float)ahrs_view->roll_sensor) / 5730.0f);
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command_filt.reset(motors->get_roll());
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target_rate_filt.reset(((float)attitude_control->get_att_target_euler_cd().x) / 5730.0f);
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rotation_rate = ((float)ahrs_view->roll_sensor) / 5730.0f;
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command_out = motors->get_roll();
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filt_target_rate = ((float)attitude_control->get_att_target_euler_cd().x) / 5730.0f;
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break;
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case PITCH:
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rotation_rate_filt.reset(((float)ahrs_view->pitch_sensor) / 5730.0f);
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command_filt.reset(motors->get_pitch());
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target_rate_filt.reset(((float)attitude_control->get_att_target_euler_cd().y) / 5730.0f);
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rotation_rate = ((float)ahrs_view->pitch_sensor) / 5730.0f;
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command_out = motors->get_pitch();
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filt_target_rate = ((float)attitude_control->get_att_target_euler_cd().y) / 5730.0f;
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break;
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case YAW:
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// yaw angle will be centered on zero by removing trim heading
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rotation_rate_filt.reset(0.0f);
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command_filt.reset(motors->get_yaw());
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target_rate_filt.reset(0.0f);
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rotation_rate = 0.0f;
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command_out = motors->get_yaw();
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filt_target_rate = 0.0f;
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break;
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}
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}
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// filter at lower frequency to remove steady state
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filt_command_reading.set_cutoff_frequency(0.2f * start_frq);
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filt_gyro_reading.set_cutoff_frequency(0.2f * start_frq);
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filt_tgt_rate_reading.set_cutoff_frequency(0.2f * start_frq);
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filt_att_fdbk_from_velxy_cd.set_cutoff_frequency(0.2f * start_frq);
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if (dwell_type == RATE) {
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filt_pit_roll_cd.set_cutoff_frequency(0.2f * start_frq);
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filt_heading_error_cd.set_cutoff_frequency(0.2f * start_frq);
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filt_att_fdbk_from_velxy_cd.set_cutoff_frequency(0.2f * start_frq);
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// save the trim output from PID controller
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float ff_term = 0.0f;
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@ -956,6 +987,13 @@ void AC_AutoTune_Heli::dwell_test_init(float start_frq, float filt_freq)
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break;
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}
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trim_pff_out = ff_term + p_term;
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}
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if (!is_equal(start_freq, stop_freq)) {
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reset_sweep_variables();
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curr_test.gain = 0.0f;
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curr_test.phase = 0.0f;
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}
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}
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void AC_AutoTune_Heli::dwell_test_run(uint8_t freq_resp_input, float start_frq, float stop_frq, float &dwell_gain, float &dwell_phase)
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@ -1163,54 +1201,6 @@ void AC_AutoTune_Heli::dwell_test_run(uint8_t freq_resp_input, float start_frq,
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}
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}
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void AC_AutoTune_Heli::angle_dwell_test_init(float start_frq, float filt_freq)
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{
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rotation_rate_filt.set_cutoff_frequency(filt_freq);
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command_filt.set_cutoff_frequency(filt_freq);
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target_rate_filt.set_cutoff_frequency(filt_freq);
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dwell_start_time_ms = 0.0f;
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settle_time = 200;
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switch (axis) {
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case ROLL:
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rotation_rate_filt.reset(((float)ahrs_view->roll_sensor) / 5730.0f);
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command_filt.reset(motors->get_roll());
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target_rate_filt.reset(((float)attitude_control->get_att_target_euler_cd().x) / 5730.0f);
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rotation_rate = ((float)ahrs_view->roll_sensor) / 5730.0f;
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command_out = motors->get_roll();
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filt_target_rate = ((float)attitude_control->get_att_target_euler_cd().x) / 5730.0f;
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break;
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case PITCH:
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rotation_rate_filt.reset(((float)ahrs_view->pitch_sensor) / 5730.0f);
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command_filt.reset(motors->get_pitch());
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target_rate_filt.reset(((float)attitude_control->get_att_target_euler_cd().y) / 5730.0f);
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rotation_rate = ((float)ahrs_view->pitch_sensor) / 5730.0f;
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command_out = motors->get_pitch();
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filt_target_rate = ((float)attitude_control->get_att_target_euler_cd().y) / 5730.0f;
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break;
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case YAW:
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// yaw angle will be centered on zero by removing trim heading
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rotation_rate_filt.reset(0.0f);
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command_filt.reset(motors->get_yaw());
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target_rate_filt.reset(0.0f);
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rotation_rate = 0.0f;
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command_out = motors->get_yaw();
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filt_target_rate = 0.0f;
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break;
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}
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// filter at lower frequency to remove steady state
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filt_command_reading.set_cutoff_frequency(0.2f * start_frq);
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filt_gyro_reading.set_cutoff_frequency(0.2f * start_frq);
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filt_tgt_rate_reading.set_cutoff_frequency(0.2f * start_frq);
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filt_att_fdbk_from_velxy_cd.set_cutoff_frequency(0.2f * start_frq);
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if (!is_equal(start_freq, stop_freq)) {
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reset_sweep_variables();
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curr_test.gain = 0.0f;
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curr_test.phase = 0.0f;
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}
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}
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void AC_AutoTune_Heli::angle_dwell_test_run(float start_frq, float stop_frq, float &dwell_gain, float &dwell_phase)
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{
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float gyro_reading = 0.0f;
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@ -136,16 +136,23 @@ private:
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// max gain data for rate d tuning
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max_gain_data max_rate_d;
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// dwell type identifies whether the dwell is ran on rate or angle
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enum DwellType {
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RATE = 0,
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ANGLE = 1,
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};
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// Feedforward test used to determine Rate FF gain
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void rate_ff_test_init();
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void rate_ff_test_run(float max_angle_cds, float target_rate_cds, float dir_sign);
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// initialize dwell test or angle dwell test variables
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void dwell_test_init(float start_frq, float filt_freq, DwellType dwell_type);
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// dwell test used to perform frequency dwells for rate gains
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void dwell_test_init(float start_frq, float filt_freq);
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void dwell_test_run(uint8_t freq_resp_input, float start_frq, float stop_frq, float &dwell_gain, float &dwell_phase);
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// dwell test used to perform frequency dwells for angle gains
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void angle_dwell_test_init(float start_frq, float filt_freq);
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void angle_dwell_test_run(float start_frq, float stop_frq, float &dwell_gain, float &dwell_phase);
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// generates waveform for frequency sweep excitations
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