2013-11-03 01:26:19 -04:00
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/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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// Traditional helicopter variables and functions
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2014-05-10 10:34:30 -03:00
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#include "heli.h"
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2013-11-03 01:26:19 -04:00
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#if FRAME_CONFIG == HELI_FRAME
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#ifndef HELI_DYNAMIC_FLIGHT_SPEED_MIN
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2013-11-16 03:58:14 -04:00
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#define HELI_DYNAMIC_FLIGHT_SPEED_MIN 500 // we are in "dynamic flight" when the speed is over 1m/s for 2 seconds
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2013-11-03 01:26:19 -04:00
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#endif
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// counter to control dynamic flight profile
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static int8_t heli_dynamic_flight_counter;
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2013-11-10 08:05:58 -04:00
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// heli_init - perform any special initialisation required for the tradheli
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static void heli_init()
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{
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2014-05-10 11:33:46 -03:00
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attitude_control.update_feedforward_filter_rates(MAIN_LOOP_SECONDS);
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2014-05-11 20:19:01 -03:00
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motors.set_dt(MAIN_LOOP_SECONDS);
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2014-07-05 11:11:27 -03:00
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// force recalculation of RSC ramp rates after setting _dt
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motors.recalc_scalers();
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2013-11-10 08:05:58 -04:00
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}
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2013-11-09 01:25:06 -04:00
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// get_pilot_desired_collective - converts pilot input (from 0 ~ 1000) to a value that can be fed into the g.rc_3.servo_out function
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static int16_t get_pilot_desired_collective(int16_t control_in)
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{
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// return immediately if reduce collective range for manual flight has not been configured
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if (g.heli_stab_col_min == 0 && g.heli_stab_col_max == 1000) {
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return control_in;
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}
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// scale pilot input to reduced collective range
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float scalar = ((float)(g.heli_stab_col_max - g.heli_stab_col_min))/1000.0f;
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int16_t collective_out = g.heli_stab_col_min + control_in * scalar;
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collective_out = constrain_int16(collective_out, 0, 1000);
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return collective_out;
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}
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2013-11-03 01:26:19 -04:00
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// heli_check_dynamic_flight - updates the dynamic_flight flag based on our horizontal velocity
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// should be called at 50hz
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static void check_dynamic_flight(void)
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{
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2014-02-03 08:06:34 -04:00
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if (!motors.armed() || !motors.motor_runup_complete() ||
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control_mode == LAND || (control_mode==RTL && rtl_state == Land) || (control_mode == AUTO && auto_mode == Auto_Land)) {
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2013-11-03 01:26:19 -04:00
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heli_dynamic_flight_counter = 0;
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heli_flags.dynamic_flight = false;
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return;
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}
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bool moving = false;
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// with GPS lock use inertial nav to determine if we are moving
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2015-01-02 07:43:50 -04:00
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if (position_ok()) {
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2013-11-03 01:26:19 -04:00
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// get horizontal velocity
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float velocity = inertial_nav.get_velocity_xy();
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moving = (velocity >= HELI_DYNAMIC_FLIGHT_SPEED_MIN);
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}else{
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// with no GPS lock base it on throttle and forward lean angle
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moving = (g.rc_3.servo_out > 800 || ahrs.pitch_sensor < -1500);
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}
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if (moving) {
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// if moving for 2 seconds, set the dynamic flight flag
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if (!heli_flags.dynamic_flight) {
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heli_dynamic_flight_counter++;
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if (heli_dynamic_flight_counter >= 100) {
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heli_flags.dynamic_flight = true;
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heli_dynamic_flight_counter = 100;
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}
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}
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}else{
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// if not moving for 2 seconds, clear the dynamic flight flag
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if (heli_flags.dynamic_flight) {
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if (heli_dynamic_flight_counter > 0) {
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heli_dynamic_flight_counter--;
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}else{
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heli_flags.dynamic_flight = false;
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}
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}
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}
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}
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2014-05-09 18:07:52 -03:00
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// update_heli_control_dynamics - pushes several important factors up into AP_MotorsHeli.
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// should be run between the rate controller and the servo updates.
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static void update_heli_control_dynamics(void)
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{
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// Use Leaky_I if we are not moving fast
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attitude_control.use_leaky_i(!heli_flags.dynamic_flight);
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// To-Do: Update dynamic phase angle of swashplate
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}
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2013-11-06 08:39:39 -04:00
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// heli_update_landing_swash - sets swash plate flag so higher minimum is used when landed or landing
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// should be called soon after update_land_detector in main code
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static void heli_update_landing_swash()
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{
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2014-02-03 08:06:34 -04:00
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switch(control_mode) {
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case ACRO:
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case STABILIZE:
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case DRIFT:
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case SPORT:
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2013-11-06 08:39:39 -04:00
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// manual modes always uses full swash range
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motors.set_collective_for_landing(false);
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break;
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2014-02-03 08:06:34 -04:00
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case LAND:
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2013-11-06 08:39:39 -04:00
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// landing always uses limit swash range
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motors.set_collective_for_landing(true);
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break;
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2014-02-03 08:06:34 -04:00
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case RTL:
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if (rtl_state == Land) {
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motors.set_collective_for_landing(true);
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}else{
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motors.set_collective_for_landing(!heli_flags.dynamic_flight || ap.land_complete || !ap.auto_armed);
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}
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break;
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case AUTO:
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if (auto_mode == Auto_Land) {
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motors.set_collective_for_landing(true);
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}else{
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motors.set_collective_for_landing(!heli_flags.dynamic_flight || ap.land_complete || !ap.auto_armed);
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}
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break;
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2013-11-06 08:39:39 -04:00
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default:
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// auto and hold use limited swash when landed
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2014-01-05 17:09:10 -04:00
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motors.set_collective_for_landing(!heli_flags.dynamic_flight || ap.land_complete || !ap.auto_armed);
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2013-11-06 08:39:39 -04:00
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break;
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}
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}
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2013-11-08 04:29:54 -04:00
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// heli_update_rotor_speed_targets - reads pilot input and passes new rotor speed targets to heli motors object
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static void heli_update_rotor_speed_targets()
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{
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// get rotor control method
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uint8_t rsc_control_mode = motors.get_rsc_mode();
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2014-05-09 18:25:25 -03:00
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int16_t rsc_control_deglitched = rotor_speed_deglitch_filter.apply(g.rc_8.control_in);
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2013-11-08 04:29:54 -04:00
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switch (rsc_control_mode) {
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case AP_MOTORS_HELI_RSC_MODE_NONE:
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// even though pilot passes rotors speed directly to rotor ESC via receiver, motor lib needs to know if
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// rotor is spinning in case we are using direct drive tailrotor which must be spun up at same time
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case AP_MOTORS_HELI_RSC_MODE_CH8_PASSTHROUGH:
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// pass through pilot desired rotor speed
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2014-05-09 18:25:25 -03:00
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motors.set_desired_rotor_speed(rsc_control_deglitched);
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2013-11-08 04:29:54 -04:00
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break;
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case AP_MOTORS_HELI_RSC_MODE_SETPOINT:
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// pass setpoint through as desired rotor speed
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2014-05-09 18:25:25 -03:00
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if (rsc_control_deglitched > 0) {
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2013-11-08 04:29:54 -04:00
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motors.set_desired_rotor_speed(motors.get_rsc_setpoint());
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}else{
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motors.set_desired_rotor_speed(0);
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}
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break;
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}
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}
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2014-01-13 04:23:09 -04:00
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#endif // FRAME_CONFIG == HELI_FRAME
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