mirror of https://github.com/ArduPilot/ardupilot
230 lines
9.5 KiB
C++
230 lines
9.5 KiB
C++
#include "mode.h"
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#include "Plane.h"
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#if HAL_QUADPLANE_ENABLED
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bool ModeQRTL::_enter()
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{
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// treat QRTL as QLAND if we are in guided wait takeoff state, to cope
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// with failsafes during GUIDED->AUTO takeoff sequence
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if (plane.quadplane.guided_wait_takeoff_on_mode_enter) {
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plane.set_mode(plane.mode_qland, ModeReason::QLAND_INSTEAD_OF_RTL);
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return true;
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}
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submode = SubMode::RTL;
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plane.prev_WP_loc = plane.current_loc;
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int32_t RTL_alt_abs_cm = plane.home.alt + quadplane.qrtl_alt*100UL;
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if (quadplane.motors->get_desired_spool_state() == AP_Motors::DesiredSpoolState::THROTTLE_UNLIMITED) {
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// VTOL motors are active, either in VTOL flight or assisted flight
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Location destination = plane.calc_best_rally_or_home_location(plane.current_loc, RTL_alt_abs_cm);
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const float dist = plane.current_loc.get_distance(destination);
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const float radius = get_VTOL_return_radius();
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// Climb at least to a cone around home of hight of QRTL alt and radius of radius
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// Always climb up to at least Q_RTL_ALT_MIN, constrain Q_RTL_ALT_MIN between Q_LAND_FINAL_ALT and Q_RTL_ALT
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const float min_climb = constrain_float(quadplane.qrtl_alt_min, quadplane.land_final_alt, quadplane.qrtl_alt);
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const float target_alt = MAX(quadplane.qrtl_alt * (dist / MAX(radius, dist)), min_climb);
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#if AP_TERRAIN_AVAILABLE
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const bool use_terrain = plane.terrain_enabled_in_mode(mode_number());
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#else
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const bool use_terrain = false;
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#endif
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const float dist_to_climb = target_alt - plane.relative_ground_altitude(plane.g.rangefinder_landing, use_terrain);
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if (is_positive(dist_to_climb)) {
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// climb before returning, only next waypoint altitude is used
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submode = SubMode::climb;
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plane.next_WP_loc = plane.current_loc;
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#if AP_TERRAIN_AVAILABLE
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int32_t curent_alt_terrain_cm;
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if (use_terrain && plane.current_loc.get_alt_cm(Location::AltFrame::ABOVE_TERRAIN, curent_alt_terrain_cm)) {
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plane.next_WP_loc.set_alt_cm(curent_alt_terrain_cm + dist_to_climb * 100UL, Location::AltFrame::ABOVE_TERRAIN);
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return true;
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}
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#endif
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plane.next_WP_loc.set_alt_cm(plane.current_loc.alt + dist_to_climb * 100UL, plane.current_loc.get_alt_frame());
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return true;
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} else if (dist < radius) {
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// Above home "cone", return at curent altitude if lower than QRTL alt
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int32_t current_alt_abs_cm;
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if (plane.current_loc.get_alt_cm(Location::AltFrame::ABSOLUTE, current_alt_abs_cm)) {
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RTL_alt_abs_cm = MIN(RTL_alt_abs_cm, current_alt_abs_cm);
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}
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// we're close to destination and already running VTOL motors, don't transition and don't climb
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gcs().send_text(MAV_SEVERITY_INFO,"VTOL position1 d=%.1f r=%.1f", dist, radius);
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poscontrol.set_state(QuadPlane::QPOS_POSITION1);
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}
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}
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// use do_RTL() to setup next_WP_loc
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plane.do_RTL(RTL_alt_abs_cm);
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quadplane.poscontrol_init_approach();
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int32_t from_alt;
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int32_t to_alt;
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if (plane.current_loc.get_alt_cm(Location::AltFrame::ABSOLUTE,from_alt) && plane.next_WP_loc.get_alt_cm(Location::AltFrame::ABSOLUTE,to_alt)) {
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poscontrol.slow_descent = from_alt > to_alt;
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return true;
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}
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// default back to old method
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poscontrol.slow_descent = (plane.current_loc.alt > plane.next_WP_loc.alt);
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return true;
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}
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void ModeQRTL::update()
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{
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plane.mode_qstabilize.update();
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}
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/*
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handle QRTL mode
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*/
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void ModeQRTL::run()
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{
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const uint32_t now = AP_HAL::millis();
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if (quadplane.tailsitter.in_vtol_transition(now)) {
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// Tailsitters in FW pull up phase of VTOL transition run FW controllers
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Mode::run();
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return;
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}
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switch (submode) {
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case SubMode::climb: {
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// request zero velocity
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Vector2f vel, accel;
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pos_control->input_vel_accel_xy(vel, accel);
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quadplane.run_xy_controller();
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// nav roll and pitch are controller by position controller
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plane.nav_roll_cd = pos_control->get_roll_cd();
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plane.nav_pitch_cd = pos_control->get_pitch_cd();
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plane.quadplane.assign_tilt_to_fwd_thr();
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if (quadplane.transition->set_VTOL_roll_pitch_limit(plane.nav_roll_cd, plane.nav_pitch_cd)) {
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pos_control->set_externally_limited_xy();
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}
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// weathervane with no pilot input
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quadplane.disable_yaw_rate_time_constant();
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attitude_control->input_euler_angle_roll_pitch_euler_rate_yaw(plane.nav_roll_cd,
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plane.nav_pitch_cd,
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quadplane.get_weathervane_yaw_rate_cds());
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// climb at full WP nav speed
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quadplane.set_climb_rate_cms(quadplane.wp_nav->get_default_speed_up());
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quadplane.run_z_controller();
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// Climb done when stopping point reaches target altitude
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Vector3p stopping_point;
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pos_control->get_stopping_point_z_cm(stopping_point.z);
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Location stopping_loc = Location(stopping_point.tofloat(), Location::AltFrame::ABOVE_ORIGIN);
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ftype alt_diff;
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if (!stopping_loc.get_alt_distance(plane.next_WP_loc, alt_diff) || is_positive(alt_diff)) {
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// climb finished or cant get alt diff, head home
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submode = SubMode::RTL;
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plane.prev_WP_loc = plane.current_loc;
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int32_t RTL_alt_abs_cm = plane.home.alt + quadplane.qrtl_alt*100UL;
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Location destination = plane.calc_best_rally_or_home_location(plane.current_loc, RTL_alt_abs_cm);
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const float dist = plane.current_loc.get_distance(destination);
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const float radius = get_VTOL_return_radius();
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if (dist < radius) {
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// if close to home return at current target altitude
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int32_t target_alt_abs_cm;
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if (plane.next_WP_loc.get_alt_cm(Location::AltFrame::ABSOLUTE, target_alt_abs_cm)) {
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RTL_alt_abs_cm = MIN(RTL_alt_abs_cm, target_alt_abs_cm);
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}
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gcs().send_text(MAV_SEVERITY_INFO,"VTOL position1 d=%.1f r=%.1f", dist, radius);
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poscontrol.set_state(QuadPlane::QPOS_POSITION1);
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}
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plane.do_RTL(RTL_alt_abs_cm);
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quadplane.poscontrol_init_approach();
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if (plane.current_loc.get_alt_distance(plane.next_WP_loc, alt_diff)) {
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poscontrol.slow_descent = is_positive(alt_diff);
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} else {
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// default back to old method
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poscontrol.slow_descent = (plane.current_loc.alt > plane.next_WP_loc.alt);
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}
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}
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break;
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}
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case SubMode::RTL: {
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quadplane.vtol_position_controller();
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if (poscontrol.get_state() > QuadPlane::QPOS_POSITION2) {
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// change target altitude to home alt
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plane.next_WP_loc.alt = plane.home.alt;
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}
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if (poscontrol.get_state() >= QuadPlane::QPOS_POSITION2) {
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// start landing logic
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quadplane.verify_vtol_land();
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}
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// when in approach allow stick mixing
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if (quadplane.poscontrol.get_state() == QuadPlane::QPOS_AIRBRAKE ||
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quadplane.poscontrol.get_state() == QuadPlane::QPOS_APPROACH) {
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plane.stabilize_stick_mixing_fbw();
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}
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break;
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}
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}
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// Stabilize with fixed wing surfaces
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plane.stabilize_roll();
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plane.stabilize_pitch();
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}
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/*
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update target altitude for QRTL profile
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*/
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void ModeQRTL::update_target_altitude()
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{
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/*
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update height target in approach
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*/
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if ((submode != SubMode::RTL) || (plane.quadplane.poscontrol.get_state() != QuadPlane::QPOS_APPROACH)) {
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Mode::update_target_altitude();
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return;
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}
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/*
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initially approach at RTL_ALT_CM, then drop down to QRTL_ALT based on maximum sink rate from TECS,
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giving time to lose speed before we transition
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*/
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const float radius = MAX(fabsf(float(plane.aparm.loiter_radius)), fabsf(float(plane.g.rtl_radius)));
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const float rtl_alt_delta = MAX(0, plane.g.RTL_altitude_cm*0.01 - plane.quadplane.qrtl_alt);
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const float sink_time = rtl_alt_delta / MAX(0.6*plane.TECS_controller.get_max_sinkrate(), 1);
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const float sink_dist = plane.aparm.airspeed_cruise_cm * 0.01 * sink_time;
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const float dist = plane.auto_state.wp_distance;
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const float rad_min = 2*radius;
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const float rad_max = 20*radius;
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float alt = linear_interpolate(0, rtl_alt_delta,
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dist,
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rad_min, MAX(rad_min, MIN(rad_max, rad_min+sink_dist)));
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Location loc = plane.next_WP_loc;
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loc.alt += alt*100;
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plane.set_target_altitude_location(loc);
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plane.altitude_error_cm = plane.calc_altitude_error_cm();
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}
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// only nudge during approach
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bool ModeQRTL::allows_throttle_nudging() const
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{
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return (submode == SubMode::RTL) && (plane.quadplane.poscontrol.get_state() == QuadPlane::QPOS_APPROACH);
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}
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// Return the radius from destination at which pure VTOL flight should be used, no transition to FW
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float ModeQRTL::get_VTOL_return_radius() const
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{
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return MAX(fabsf(float(plane.aparm.loiter_radius)), fabsf(float(plane.g.rtl_radius))) * 1.5;
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}
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#endif
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