2019-01-15 13:46:13 -04:00
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#include "mode.h"
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#include "Plane.h"
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bool ModeAcro::_enter()
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{
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2023-02-12 09:45:25 -04:00
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acro_state.locked_roll = false;
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acro_state.locked_pitch = false;
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IGNORE_RETURN(ahrs.get_quaternion(acro_state.q));
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2019-01-15 13:46:13 -04:00
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return true;
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}
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void ModeAcro::update()
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{
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// handle locked/unlocked control
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2023-02-12 09:45:25 -04:00
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if (acro_state.locked_roll) {
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plane.nav_roll_cd = acro_state.locked_roll_err;
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2019-01-15 13:46:13 -04:00
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} else {
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2023-02-12 09:33:27 -04:00
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plane.nav_roll_cd = ahrs.roll_sensor;
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2019-01-15 13:46:13 -04:00
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}
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2023-02-12 09:45:25 -04:00
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if (acro_state.locked_pitch) {
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plane.nav_pitch_cd = acro_state.locked_pitch_cd;
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2019-01-15 13:46:13 -04:00
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} else {
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2023-02-12 09:33:27 -04:00
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plane.nav_pitch_cd = ahrs.pitch_sensor;
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2019-01-15 13:46:13 -04:00
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}
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}
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2023-02-20 20:45:28 -04:00
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void ModeAcro::run()
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{
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if (plane.g.acro_locking == 2 && plane.g.acro_yaw_rate > 0 &&
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plane.yawController.rate_control_enabled()) {
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// we can do 3D acro locking
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stabilize_quaternion();
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return;
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}
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// Normal acro
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stabilize();
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}
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/*
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this is the ACRO mode stabilization function. It does rate
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stabilization on roll and pitch axes
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*/
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void ModeAcro::stabilize()
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{
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const float speed_scaler = plane.get_speed_scaler();
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const float rexpo = plane.roll_in_expo(true);
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const float pexpo = plane.pitch_in_expo(true);
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float roll_rate = (rexpo/SERVO_MAX) * plane.g.acro_roll_rate;
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float pitch_rate = (pexpo/SERVO_MAX) * plane.g.acro_pitch_rate;
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IGNORE_RETURN(ahrs.get_quaternion(acro_state.q));
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/*
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check for special roll handling near the pitch poles
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*/
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if (plane.g.acro_locking && is_zero(roll_rate)) {
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/*
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we have no roll stick input, so we will enter "roll locked"
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mode, and hold the roll we had when the stick was released
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*/
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if (!acro_state.locked_roll) {
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acro_state.locked_roll = true;
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acro_state.locked_roll_err = 0;
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} else {
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acro_state.locked_roll_err += ahrs.get_gyro().x * plane.G_Dt;
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}
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int32_t roll_error_cd = -ToDeg(acro_state.locked_roll_err)*100;
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plane.nav_roll_cd = ahrs.roll_sensor + roll_error_cd;
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// try to reduce the integrated angular error to zero. We set
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2023-10-11 04:41:54 -03:00
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// 'stabilize' to true, which disables the roll integrator
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2023-02-20 20:45:28 -04:00
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SRV_Channels::set_output_scaled(SRV_Channel::k_aileron, plane.rollController.get_servo_out(roll_error_cd,
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speed_scaler,
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true, false));
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} else {
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/*
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aileron stick is non-zero, use pure rate control until the
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user releases the stick
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*/
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acro_state.locked_roll = false;
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SRV_Channels::set_output_scaled(SRV_Channel::k_aileron, plane.rollController.get_rate_out(roll_rate, speed_scaler));
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}
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if (plane.g.acro_locking && is_zero(pitch_rate)) {
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/*
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user has zero pitch stick input, so we lock pitch at the
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point they release the stick
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*/
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if (!acro_state.locked_pitch) {
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acro_state.locked_pitch = true;
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acro_state.locked_pitch_cd = ahrs.pitch_sensor;
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}
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// try to hold the locked pitch. Note that we have the pitch
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// integrator enabled, which helps with inverted flight
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plane.nav_pitch_cd = acro_state.locked_pitch_cd;
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SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, plane.pitchController.get_servo_out(plane.nav_pitch_cd - ahrs.pitch_sensor,
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speed_scaler,
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false, false));
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} else {
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/*
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user has non-zero pitch input, use a pure rate controller
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*/
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acro_state.locked_pitch = false;
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SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, plane.pitchController.get_rate_out(pitch_rate, speed_scaler));
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}
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2023-07-05 20:01:16 -03:00
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float rudder_output;
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2023-02-20 20:45:28 -04:00
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if (plane.g.acro_yaw_rate > 0 && plane.yawController.rate_control_enabled()) {
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// user has asked for yaw rate control with yaw rate scaled by ACRO_YAW_RATE
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const float rudd_expo = plane.rudder_in_expo(true);
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const float yaw_rate = (rudd_expo/SERVO_MAX) * plane.g.acro_yaw_rate;
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2023-07-05 20:01:16 -03:00
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rudder_output = plane.yawController.get_rate_out(yaw_rate, speed_scaler, false);
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2023-04-26 00:27:13 -03:00
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} else if (plane.flight_option_enabled(FlightOptions::ACRO_YAW_DAMPER)) {
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// use yaw controller
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rudder_output = plane.calc_nav_yaw_coordinated();
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2023-02-20 20:45:28 -04:00
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} else {
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/*
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manual rudder
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*/
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rudder_output = plane.rudder_input();
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2023-02-20 20:45:28 -04:00
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}
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2023-07-05 20:01:16 -03:00
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output_rudder_and_steering(rudder_output);
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2023-02-20 20:45:28 -04:00
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}
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/*
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quaternion based acro stabilization with continuous locking. Enabled with ACRO_LOCKING=2
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*/
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void ModeAcro::stabilize_quaternion()
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{
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const float speed_scaler = plane.get_speed_scaler();
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auto &q = acro_state.q;
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const float rexpo = plane.roll_in_expo(true);
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const float pexpo = plane.pitch_in_expo(true);
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const float yexpo = plane.rudder_in_expo(true);
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// get pilot desired rates
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float roll_rate = (rexpo/SERVO_MAX) * plane.g.acro_roll_rate;
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float pitch_rate = (pexpo/SERVO_MAX) * plane.g.acro_pitch_rate;
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float yaw_rate = (yexpo/SERVO_MAX) * plane.g.acro_yaw_rate;
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bool roll_active = !is_zero(roll_rate);
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bool pitch_active = !is_zero(pitch_rate);
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bool yaw_active = !is_zero(yaw_rate);
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// integrate target attitude
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Vector3f r{ float(radians(roll_rate)), float(radians(pitch_rate)), float(radians(yaw_rate)) };
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r *= plane.G_Dt;
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q.rotate_fast(r);
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q.normalize();
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// fill in target roll/pitch for GCS/logs
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plane.nav_roll_cd = degrees(q.get_euler_roll())*100;
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plane.nav_pitch_cd = degrees(q.get_euler_pitch())*100;
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// get AHRS attitude
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Quaternion ahrs_q;
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IGNORE_RETURN(ahrs.get_quaternion(ahrs_q));
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// zero target if not flying, no stick input and zero throttle
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if (is_zero(plane.get_throttle_input()) &&
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!plane.is_flying() &&
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is_zero(roll_rate) &&
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is_zero(pitch_rate) &&
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is_zero(yaw_rate)) {
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// cope with sitting on the ground with neutral sticks, no throttle
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q = ahrs_q;
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}
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// get error in attitude
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Quaternion error_quat = ahrs_q.inverse() * q;
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Vector3f error_angle1;
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error_quat.to_axis_angle(error_angle1);
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// don't let too much error build up, limit to 0.2s
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const float max_error_t = 0.2;
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float max_err_roll_rad = radians(plane.g.acro_roll_rate*max_error_t);
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float max_err_pitch_rad = radians(plane.g.acro_pitch_rate*max_error_t);
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float max_err_yaw_rad = radians(plane.g.acro_yaw_rate*max_error_t);
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if (!roll_active && acro_state.roll_active_last) {
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max_err_roll_rad = 0;
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}
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if (!pitch_active && acro_state.pitch_active_last) {
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max_err_pitch_rad = 0;
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}
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if (!yaw_active && acro_state.yaw_active_last) {
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max_err_yaw_rad = 0;
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}
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Vector3f desired_rates = error_angle1;
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desired_rates.x = constrain_float(desired_rates.x, -max_err_roll_rad, max_err_roll_rad);
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desired_rates.y = constrain_float(desired_rates.y, -max_err_pitch_rad, max_err_pitch_rad);
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desired_rates.z = constrain_float(desired_rates.z, -max_err_yaw_rad, max_err_yaw_rad);
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// correct target based on max error
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q.rotate_fast(desired_rates - error_angle1);
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q.normalize();
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// convert to desired body rates
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desired_rates.x /= plane.rollController.tau();
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desired_rates.y /= plane.pitchController.tau();
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desired_rates.z /= plane.pitchController.tau(); // no yaw tau parameter, use pitch
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desired_rates *= degrees(1.0);
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if (roll_active) {
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desired_rates.x = roll_rate;
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}
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if (pitch_active) {
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desired_rates.y = pitch_rate;
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}
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if (yaw_active) {
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desired_rates.z = yaw_rate;
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}
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// call to rate controllers
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SRV_Channels::set_output_scaled(SRV_Channel::k_aileron, plane.rollController.get_rate_out(desired_rates.x, speed_scaler));
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SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, plane.pitchController.get_rate_out(desired_rates.y, speed_scaler));
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2023-07-05 20:01:16 -03:00
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output_rudder_and_steering(plane.yawController.get_rate_out(desired_rates.z, speed_scaler, false));
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2023-02-20 20:45:28 -04:00
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acro_state.roll_active_last = roll_active;
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acro_state.pitch_active_last = pitch_active;
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acro_state.yaw_active_last = yaw_active;
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}
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