mirror of https://github.com/ArduPilot/ardupilot
277 lines
7.9 KiB
Plaintext
277 lines
7.9 KiB
Plaintext
/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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void
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init_pids()
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{
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// create limits to how much dampening we'll allow
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// this creates symmetry with the P gain value preventing oscillations
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max_stabilize_dampener = g.pid_stabilize_roll.kP() * 2500; // = 0.6 * 2500 = 1500 or 15°
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max_yaw_dampener = g.pid_yaw.kP() * 6000; // = .5 * 6000 = 3000
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}
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void
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control_nav_mixer()
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{
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// control +- 45° is mixed with the navigation request by the Autopilot
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// output is in degrees = target pitch and roll of copter
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g.rc_1.servo_out = g.rc_1.control_mix(nav_roll);
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g.rc_2.servo_out = g.rc_2.control_mix(nav_pitch);
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}
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void
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fbw_nav_mixer()
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{
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// control +- 45° is mixed with the navigation request by the Autopilot
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// output is in degrees = target pitch and roll of copter
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g.rc_1.servo_out = nav_roll;
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g.rc_2.servo_out = nav_pitch;
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}
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void
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output_stabilize_roll()
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{
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float error, rate;
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int dampener;
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error = g.rc_1.servo_out - dcm.roll_sensor;
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// limit the error we're feeding to the PID
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error = constrain(error, -2500, 2500);
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// write out angles back to servo out - this will be converted to PWM by RC_Channel
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g.rc_1.servo_out = g.pid_stabilize_roll.get_pid(error, delta_ms_fast_loop, 1.0);
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// We adjust the output by the rate of rotation:
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// Rate control through bias corrected gyro rates
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// omega is the raw gyro reading
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// Limit dampening to be equal to propotional term for symmetry
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rate = degrees(omega.x) * 100.0; // 6rad = 34377
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dampener = (rate * g.stabilize_dampener); // 34377 * .175 = 6000
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g.rc_1.servo_out -= constrain(dampener, -max_stabilize_dampener, max_stabilize_dampener); // limit to 1500 based on kP
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}
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void
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output_stabilize_pitch()
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{
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float error, rate;
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int dampener;
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error = g.rc_2.servo_out - dcm.pitch_sensor;
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// limit the error we're feeding to the PID
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error = constrain(error, -2500, 2500);
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// write out angles back to servo out - this will be converted to PWM by RC_Channel
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g.rc_2.servo_out = g.pid_stabilize_pitch.get_pid(error, delta_ms_fast_loop, 1.0);
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// We adjust the output by the rate of rotation:
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// Rate control through bias corrected gyro rates
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// omega is the raw gyro reading
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// Limit dampening to be equal to propotional term for symmetry
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rate = degrees(omega.y) * 100.0; // 6rad = 34377
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dampener = (rate * g.stabilize_dampener); // 34377 * .175 = 6000
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g.rc_2.servo_out -= constrain(dampener, -max_stabilize_dampener, max_stabilize_dampener); // limit to 1500 based on kP
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}
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void
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clear_yaw_control()
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{
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//Serial.print("Clear ");
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rate_yaw_flag = false; // exit rate_yaw_flag
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nav_yaw = dcm.yaw_sensor; // save our Yaw
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yaw_error = 0;
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}
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void
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output_yaw_with_hold(boolean hold)
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{
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if(hold){
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// look to see if we have exited rate control properly - ie stopped turning
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if(rate_yaw_flag){
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// we are still in motion from rate control
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if(fabs(omega.z) < .5){
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clear_yaw_control();
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hold = true; // just to be explicit
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//Serial.print("C");
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}else{
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// return to rate control until we slow down.
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hold = false;
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//Serial.print("D");
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}
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}
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}else{
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// rate control
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// this indicates we are under rate control, when we enter Yaw Hold and
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// return to 0° per second, we exit rate control and hold the current Yaw
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rate_yaw_flag = true;
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yaw_error = 0;
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}
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if(hold){
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// try and hold the current nav_yaw setting
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yaw_error = nav_yaw - dcm.yaw_sensor; // +- 60°
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yaw_error = wrap_180(yaw_error);
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// limit the error we're feeding to the PID
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yaw_error = constrain(yaw_error, -6000, 6000); // limit error to 60 degees
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// Apply PID and save the new angle back to RC_Channel
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g.rc_4.servo_out = g.pid_yaw.get_pid(yaw_error, delta_ms_fast_loop, 1.0); // .5 * 6000 = 3000
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// We adjust the output by the rate of rotation
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long rate = degrees(omega.z) * 100.0; // 3rad = 17188 , 6rad = 34377
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int dampener = ((float)rate * g.hold_yaw_dampener); // 18000 * .17 = 3000
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// Limit dampening to be equal to propotional term for symmetry
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g.rc_4.servo_out -= constrain(dampener, -max_yaw_dampener, max_yaw_dampener); // -3000
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}else{
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// rate control
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long rate = degrees(omega.z) * 100; // 3rad = 17188 , 6rad = 34377
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rate = constrain(rate, -36000, 36000); // limit to something fun!
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long error = ((long)g.rc_4.control_in * 6) - rate; // control is += 6000 * 6 = 36000
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// -error = CCW, +error = CW
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if(g.rc_4.control_in == 0){
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// we are breaking;
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g.rc_4.servo_out = (omega.z > 0) ? -1800 : 1800;
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//switch comments to get old behavior.
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//g.rc_4.servo_out = g.pid_acro_rate_yaw.get_pid(error, delta_ms_fast_loop, 1.0);// kP .07 * 36000 = 2520
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}else{
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g.rc_4.servo_out = g.pid_acro_rate_yaw.get_pid(error, delta_ms_fast_loop, 1.0);// kP .07 * 36000 = 2520
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}
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g.rc_4.servo_out = constrain(g.rc_4.servo_out, -1800, 1800); // limit to 24°
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}
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}
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// slight left rudder gives right roll.
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void
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output_rate_roll()
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{
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// rate control
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long rate = degrees(omega.x) * 100; // 3rad = 17188 , 6rad = 34377
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rate = constrain(rate, -36000, 36000); // limit to something fun!
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long error = ((long)g.rc_1.control_in * 8) - rate; // control is += 4500 * 8 = 36000
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g.rc_1.servo_out = g.pid_acro_rate_roll.get_pid(error, delta_ms_fast_loop, 1.0); // .075 * 36000 = 2700
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g.rc_1.servo_out = constrain(g.rc_1.servo_out, -2400, 2400); // limit to 2400
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}
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void
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output_rate_pitch()
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{
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// rate control
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long rate = degrees(omega.y) * 100; // 3rad = 17188 , 6rad = 34377
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rate = constrain(rate, -36000, 36000); // limit to something fun!
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long error = ((long)g.rc_2.control_in * 8) - rate; // control is += 4500 * 8 = 36000
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g.rc_2.servo_out = g.pid_acro_rate_pitch.get_pid(error, delta_ms_fast_loop, 1.0); // .075 * 36000 = 2700
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g.rc_2.servo_out = constrain(g.rc_2.servo_out, -2400, 2400); // limit to 2400
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}
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// Zeros out navigation Integrators if we are changing mode, have passed a waypoint, etc.
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// Keeps outdated data out of our calculations
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void
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reset_I(void)
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{
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g.pid_nav_lat.reset_I();
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g.pid_nav_lon.reset_I();
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g.pid_baro_throttle.reset_I();
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g.pid_sonar_throttle.reset_I();
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}
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/*************************************************************
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throttle control
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****************************************************************/
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// user input:
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// -----------
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void output_manual_throttle()
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{
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g.rc_3.servo_out = (float)g.rc_3.control_in * angle_boost();
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}
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// Autopilot
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// ---------
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void output_auto_throttle()
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{
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g.rc_3.servo_out = (float)nav_throttle * angle_boost();
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// make sure we never send a 0 throttle that will cut the motors
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g.rc_3.servo_out = max(g.rc_3.servo_out, 1);
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}
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void calc_nav_throttle()
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{
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// limit error
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long error = constrain(altitude_error, -400, 400);
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float scaler = 1.0;
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if(error < 0){
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scaler = (altitude_sensor == BARO) ? .5 : .5;
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}
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if(altitude_sensor == BARO){
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nav_throttle = g.pid_baro_throttle.get_pid(error, delta_ms_fast_loop, scaler);
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nav_throttle = g.throttle_cruise + constrain(nav_throttle, -30, 80);
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}else{
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nav_throttle = g.pid_sonar_throttle.get_pid(error, delta_ms_fast_loop, scaler);
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nav_throttle = g.throttle_cruise + constrain(nav_throttle, -60, 100);
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}
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nav_throttle = (nav_throttle + nav_throttle_old) >> 1;
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nav_throttle_old = nav_throttle;
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//Serial.printf("nav_thr %d, scaler %2.2f ", nav_throttle, scaler);
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}
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float angle_boost()
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{
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float temp = cos_pitch_x * cos_roll_x;
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temp = 2.0 - constrain(temp, .7, 1.0);
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return temp;
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}
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/*************************************************************
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yaw control
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****************************************************************/
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void output_manual_yaw()
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{
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if(g.rc_3.control_in == 0){
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clear_yaw_control();
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}else{
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// Yaw control
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if(g.rc_4.control_in == 0){
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output_yaw_with_hold(true); // hold yaw
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}else{
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output_yaw_with_hold(false); // rate control yaw
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}
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}
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}
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void auto_yaw()
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{
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if(nav_yaw_towards_wp){
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nav_yaw = target_bearing;
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}
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output_yaw_with_hold(true); // hold yaw
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}
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