mirror of https://github.com/ArduPilot/ardupilot
472 lines
19 KiB
C++
472 lines
19 KiB
C++
#include "Plane.h"
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/*
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control code for tiltrotors and tiltwings. Enabled by setting
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Q_TILT_MASK to a non-zero value
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*/
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/*
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calculate maximum tilt change as a proportion from 0 to 1 of tilt
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*/
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float QuadPlane::tilt_max_change(bool up) const
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{
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float rate;
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if (up || tilt.max_rate_down_dps <= 0) {
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rate = tilt.max_rate_up_dps;
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} else {
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rate = tilt.max_rate_down_dps;
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}
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if (tilt.tilt_type != TILT_TYPE_BINARY && !up) {
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bool fast_tilt = false;
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if (plane.control_mode == &plane.mode_manual) {
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fast_tilt = true;
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}
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if (hal.util->get_soft_armed() && !in_vtol_mode() && !assisted_flight) {
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fast_tilt = true;
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}
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if (fast_tilt) {
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// allow a minimum of 90 DPS in manual or if we are not
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// stabilising, to give fast control
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rate = MAX(rate, 90);
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}
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}
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return rate * plane.G_Dt / 90.0f;
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}
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/*
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output a slew limited tiltrotor angle. tilt is from 0 to 1
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*/
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void QuadPlane::tiltrotor_slew(float newtilt)
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{
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float max_change = tilt_max_change(newtilt<tilt.current_tilt);
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tilt.current_tilt = constrain_float(newtilt, tilt.current_tilt-max_change, tilt.current_tilt+max_change);
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// translate to 0..1000 range and output
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SRV_Channels::set_output_scaled(SRV_Channel::k_motor_tilt, 1000 * tilt.current_tilt);
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}
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/*
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update motor tilt for continuous tilt servos
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*/
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void QuadPlane::tiltrotor_continuous_update(void)
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{
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// default to inactive
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tilt.motors_active = false;
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// the maximum rate of throttle change
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float max_change;
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if (!in_vtol_mode() && (!hal.util->get_soft_armed() || !assisted_flight)) {
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// we are in pure fixed wing mode. Move the tiltable motors all the way forward and run them as
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// a forward motor
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tiltrotor_slew(1);
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max_change = tilt_max_change(false);
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float new_throttle = constrain_float(SRV_Channels::get_output_scaled(SRV_Channel::k_throttle)*0.01, 0, 1);
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if (tilt.current_tilt < 1) {
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tilt.current_throttle = constrain_float(new_throttle,
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tilt.current_throttle-max_change,
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tilt.current_throttle+max_change);
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} else {
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tilt.current_throttle = new_throttle;
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}
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if (!hal.util->get_soft_armed()) {
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tilt.current_throttle = 0;
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} else {
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// prevent motor shutdown
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tilt.motors_active = true;
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}
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if (!motor_test.running) {
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// the motors are all the way forward, start using them for fwd thrust
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uint8_t mask = is_zero(tilt.current_throttle)?0:(uint8_t)tilt.tilt_mask.get();
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motors->output_motor_mask(tilt.current_throttle, mask, plane.rudder_dt);
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}
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return;
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}
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// remember the throttle level we're using for VTOL flight
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float motors_throttle = motors->get_throttle();
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max_change = tilt_max_change(motors_throttle<tilt.current_throttle);
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tilt.current_throttle = constrain_float(motors_throttle,
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tilt.current_throttle-max_change,
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tilt.current_throttle+max_change);
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/*
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we are in a VTOL mode. We need to work out how much tilt is
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needed. There are 4 strategies we will use:
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1) without manual forward throttle control, the angle will be set to zero
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in QAUTOTUNE QACRO, QSTABILIZE and QHOVER. This
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enables these modes to be used as a safe recovery mode.
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2) with manual forward throttle control we will set the angle based on
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the demanded forward throttle via RC input.
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3) in fixed wing assisted flight or velocity controlled modes we
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will set the angle based on the demanded forward throttle,
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with a maximum tilt given by Q_TILT_MAX. This relies on
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Q_VFWD_GAIN being set.
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4) if we are in TRANSITION_TIMER mode then we are transitioning
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to forward flight and should put the rotors all the way forward
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*/
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if (plane.control_mode == &plane.mode_qautotune) {
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tiltrotor_slew(0);
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return;
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}
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// if not in assisted flight and in QACRO, QSTABILIZE or QHOVER mode
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if (!assisted_flight &&
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(plane.control_mode == &plane.mode_qacro ||
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plane.control_mode == &plane.mode_qstabilize ||
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plane.control_mode == &plane.mode_qhover)) {
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if (rc_fwd_thr_ch == nullptr) {
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// no manual throttle control, set angle to zero
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tiltrotor_slew(0);
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} else {
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// manual control of forward throttle
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float settilt = .01f * forward_throttle_pct();
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tiltrotor_slew(settilt);
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}
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return;
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}
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if (assisted_flight &&
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transition_state >= TRANSITION_TIMER) {
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// we are transitioning to fixed wing - tilt the motors all
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// the way forward
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tiltrotor_slew(1);
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} else {
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// until we have completed the transition we limit the tilt to
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// Q_TILT_MAX. Anything above 50% throttle gets
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// Q_TILT_MAX. Below 50% throttle we decrease linearly. This
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// relies heavily on Q_VFWD_GAIN being set appropriately.
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float settilt = constrain_float(SRV_Channels::get_output_scaled(SRV_Channel::k_throttle) / 50.0f, 0, 1);
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tiltrotor_slew(settilt * tilt.max_angle_deg / 90.0f);
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}
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}
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/*
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output a slew limited tiltrotor angle. tilt is 0 or 1
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*/
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void QuadPlane::tiltrotor_binary_slew(bool forward)
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{
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// The servo output is binary, not slew rate limited
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SRV_Channels::set_output_scaled(SRV_Channel::k_motor_tilt, forward?1000:0);
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// rate limiting current_tilt has the effect of delaying throttle in tiltrotor_binary_update
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float max_change = tilt_max_change(!forward);
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if (forward) {
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tilt.current_tilt = constrain_float(tilt.current_tilt+max_change, 0, 1);
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} else {
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tilt.current_tilt = constrain_float(tilt.current_tilt-max_change, 0, 1);
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}
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}
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/*
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update motor tilt for binary tilt servos
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*/
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void QuadPlane::tiltrotor_binary_update(void)
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{
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// motors always active
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tilt.motors_active = true;
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if (!in_vtol_mode()) {
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// we are in pure fixed wing mode. Move the tiltable motors
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// all the way forward and run them as a forward motor
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tiltrotor_binary_slew(true);
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float new_throttle = SRV_Channels::get_output_scaled(SRV_Channel::k_throttle)*0.01f;
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if (tilt.current_tilt >= 1) {
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uint8_t mask = is_zero(new_throttle)?0:(uint8_t)tilt.tilt_mask.get();
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// the motors are all the way forward, start using them for fwd thrust
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motors->output_motor_mask(new_throttle, mask, plane.rudder_dt);
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}
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} else {
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tiltrotor_binary_slew(false);
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}
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}
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/*
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update motor tilt
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*/
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void QuadPlane::tiltrotor_update(void)
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{
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if (tilt.tilt_mask <= 0) {
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// no motors to tilt
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return;
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}
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if (tilt.tilt_type == TILT_TYPE_BINARY) {
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tiltrotor_binary_update();
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} else {
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tiltrotor_continuous_update();
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}
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if (tilt.tilt_type == TILT_TYPE_VECTORED_YAW) {
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tiltrotor_vectoring();
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}
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}
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/*
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tilt compensation for angle of tilt. When the rotors are tilted the
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roll effect of differential thrust on the tilted rotors is decreased
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and the yaw effect increased
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We have two factors we apply.
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1) when we are transitioning to fwd flight we scale the tilted rotors by 1/cos(angle). This pushes us towards more flight speed
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2) when we are transitioning to hover we scale the non-tilted rotors by cos(angle). This pushes us towards lower fwd thrust
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We also apply an equalisation to the tilted motors in proportion to
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how much tilt we have. This smoothly reduces the impact of the roll
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gains as we tilt further forward.
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For yaw, we apply differential thrust in proportion to the demanded
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yaw control and sin of the tilt angle
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Finally we ensure no requested thrust is over 1 by scaling back all
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motors so the largest thrust is at most 1.0
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*/
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void QuadPlane::tilt_compensate_angle(float *thrust, uint8_t num_motors, float non_tilted_mul, float tilted_mul)
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{
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float tilt_total = 0;
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uint8_t tilt_count = 0;
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// apply tilt_factors first
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for (uint8_t i=0; i<num_motors; i++) {
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if (!is_motor_tilting(i)) {
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thrust[i] *= non_tilted_mul;
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} else {
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thrust[i] *= tilted_mul;
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tilt_total += thrust[i];
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tilt_count++;
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}
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}
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float largest_tilted = 0;
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const float sin_tilt = sinf(radians(tilt.current_tilt*90));
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// yaw_gain relates the amount of differential thrust we get from
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// tilt, so that the scaling of the yaw control is the same at any
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// tilt angle
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const float yaw_gain = sinf(radians(tilt.tilt_yaw_angle));
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const float avg_tilt_thrust = tilt_total / tilt_count;
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for (uint8_t i=0; i<num_motors; i++) {
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if (is_motor_tilting(i)) {
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// as we tilt we need to reduce the impact of the roll
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// controller. This simple method keeps the same average,
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// but moves us to no roll control as the angle increases
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thrust[i] = tilt.current_tilt * avg_tilt_thrust + thrust[i] * (1-tilt.current_tilt);
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// add in differential thrust for yaw control, scaled by tilt angle
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const float diff_thrust = motors->get_roll_factor(i) * motors->get_yaw() * sin_tilt * yaw_gain;
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thrust[i] += diff_thrust;
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largest_tilted = MAX(largest_tilted, thrust[i]);
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}
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}
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// if we are saturating one of the motors then reduce all motors
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// to keep them in proportion to the original thrust. This helps
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// maintain stability when tilted at a large angle
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if (largest_tilted > 1.0f) {
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float scale = 1.0f / largest_tilted;
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for (uint8_t i=0; i<num_motors; i++) {
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thrust[i] *= scale;
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}
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}
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}
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/*
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choose up or down tilt compensation based on flight mode When going
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to a fixed wing mode we use tilt_compensate_down, when going to a
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VTOL mode we use tilt_compensate_up
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*/
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void QuadPlane::tilt_compensate(float *thrust, uint8_t num_motors)
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{
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if (tilt.current_tilt <= 0) {
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// the motors are not tilted, no compensation needed
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return;
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}
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if (in_vtol_mode()) {
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// we are transitioning to VTOL flight
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const float tilt_factor = cosf(radians(tilt.current_tilt*90));
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tilt_compensate_angle(thrust, num_motors, tilt_factor, 1);
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} else {
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float inv_tilt_factor;
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if (tilt.current_tilt > 0.98f) {
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inv_tilt_factor = 1.0 / cosf(radians(0.98f*90));
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} else {
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inv_tilt_factor = 1.0 / cosf(radians(tilt.current_tilt*90));
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}
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tilt_compensate_angle(thrust, num_motors, 1, inv_tilt_factor);
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}
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}
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/*
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return true if the rotors are fully tilted forward
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*/
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bool QuadPlane::tiltrotor_fully_fwd(void) const
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{
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if (tilt.tilt_mask <= 0) {
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return false;
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}
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return (tilt.current_tilt >= 1);
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}
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/*
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return scaling factor for tilt rotors by throttle
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we want to scale back tilt angle for roll/pitch by throttle in
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forward flight
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*/
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float QuadPlane::tilt_throttle_scaling(void)
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{
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const float throttle = SRV_Channels::get_output_scaled(SRV_Channel::k_throttle) * 0.01;
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// scale relative to a fixed 0.5 mid throttle so that changes in TRIM_THROTTLE in missions don't change
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// the scaling of tilt
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const float mid_throttle = 0.5;
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return mid_throttle / constrain_float(throttle, 0.1, 1.0);
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}
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/*
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control vectoring for tilt multicopters
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*/
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void QuadPlane::tiltrotor_vectoring(void)
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{
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// total angle the tilt can go through
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const float total_angle = 90 + tilt.tilt_yaw_angle + tilt.fixed_angle;
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// output value (0 to 1) to get motors pointed straight up
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const float zero_out = tilt.tilt_yaw_angle / total_angle;
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const float fixed_tilt_limit = tilt.fixed_angle / total_angle;
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const float level_out = 1.0 - fixed_tilt_limit;
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// calculate the basic tilt amount from current_tilt
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float base_output = zero_out + (tilt.current_tilt * (level_out - zero_out));
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// for testing when disarmed, apply vectored yaw in proportion to rudder stick
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// Wait TILT_DELAY_MS after disarming to allow props to spin down first.
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constexpr uint32_t TILT_DELAY_MS = 3000;
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uint32_t now = AP_HAL::millis();
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if (!hal.util->get_soft_armed() && (plane.quadplane.options & OPTION_DISARMED_TILT)) {
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// this test is subject to wrapping at ~49 days, but the consequences are insignificant
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if ((now - hal.util->get_last_armed_change()) > TILT_DELAY_MS) {
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if (in_vtol_mode()) {
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float yaw_out = plane.channel_rudder->get_control_in();
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yaw_out /= plane.channel_rudder->get_range();
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float yaw_range = zero_out;
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, 1000 * constrain_float(base_output + yaw_out * yaw_range,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, 1000 * constrain_float(base_output - yaw_out * yaw_range,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft, 1000 * constrain_float(base_output + yaw_out * yaw_range,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight, 1000 * constrain_float(base_output - yaw_out * yaw_range,0,1));
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} else {
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// fixed wing tilt
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const float gain = tilt.fixed_gain * fixed_tilt_limit;
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// base the tilt on elevon mixing, which means it
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// takes account of the MIXING_GAIN. The rear tilt is
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// based on elevator
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const float right = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_right) / 4500.0;
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const float left = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_left) / 4500.0;
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const float mid = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevator) / 4500.0;
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// front tilt is effective canards, so need to swap and use negative. Rear motors are treated live elevons.
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft,1000 * constrain_float(base_output - right,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight,1000 * constrain_float(base_output - left,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft,1000 * constrain_float(base_output + left,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight,1000 * constrain_float(base_output + right,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output + mid,0,1));
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}
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}
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return;
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}
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float tilt_threshold = (tilt.max_angle_deg/90.0f);
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bool no_yaw = (tilt.current_tilt > tilt_threshold);
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if (no_yaw) {
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// fixed wing tilt. We need to apply inverse scaling with throttle, and remove the surface speed scaling as
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// we don't want tilt impacted by airspeed
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const float scaler = plane.control_mode == &plane.mode_manual?1:(tilt_throttle_scaling() / plane.get_speed_scaler());
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const float gain = tilt.fixed_gain * fixed_tilt_limit * scaler;
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const float right = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_right) / 4500.0;
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const float left = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_left) / 4500.0;
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const float mid = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevator) / 4500.0;
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft,1000 * constrain_float(base_output - right,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight,1000 * constrain_float(base_output - left,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft,1000 * constrain_float(base_output + left,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight,1000 * constrain_float(base_output + right,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output + mid,0,1));
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} else {
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const float yaw_out = motors->get_yaw();
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const float roll_out = motors->get_roll();
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float yaw_range = zero_out;
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// now apply vectored thrust for yaw and roll.
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const float tilt_rad = radians(tilt.current_tilt*90);
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const float sin_tilt = sinf(tilt_rad);
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const float cos_tilt = cosf(tilt_rad);
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// the MotorsMatrix library normalises roll factor to 0.5, so
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// we need to use the same factor here to keep the same roll
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// gains when tilted as we have when not tilted
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const float avg_roll_factor = 0.5;
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const float tilt_offset = constrain_float(yaw_out * cos_tilt + avg_roll_factor * roll_out * sin_tilt, -1, 1);
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, 1000 * constrain_float(base_output + tilt_offset * yaw_range,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, 1000 * constrain_float(base_output - tilt_offset * yaw_range,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output,0,1));
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SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft, 1000 * constrain_float(base_output + tilt_offset * yaw_range,0,1));
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|
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight, 1000 * constrain_float(base_output - tilt_offset * yaw_range,0,1));
|
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}
|
|
}
|
|
|
|
/*
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|
control bicopter tiltrotors
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|
*/
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|
void QuadPlane::tiltrotor_bicopter(void)
|
|
{
|
|
if (tilt.tilt_type != TILT_TYPE_BICOPTER || motor_test.running) {
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|
// don't override motor test with motors_output
|
|
return;
|
|
}
|
|
|
|
if (!in_vtol_mode() && tiltrotor_fully_fwd()) {
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|
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, -SERVO_MAX);
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|
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, -SERVO_MAX);
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|
return;
|
|
}
|
|
|
|
float throttle = SRV_Channels::get_output_scaled(SRV_Channel::k_throttle);
|
|
if (assisted_flight) {
|
|
hold_stabilize(throttle * 0.01f);
|
|
motors_output(true);
|
|
} else {
|
|
motors_output(false);
|
|
}
|
|
|
|
// bicopter assumes that trim is up so we scale down so match
|
|
float tilt_left = SRV_Channels::get_output_scaled(SRV_Channel::k_tiltMotorLeft);
|
|
float tilt_right = SRV_Channels::get_output_scaled(SRV_Channel::k_tiltMotorRight);
|
|
|
|
if (is_negative(tilt_left)) {
|
|
tilt_left *= tilt.tilt_yaw_angle / 90.0f;
|
|
}
|
|
if (is_negative(tilt_right)) {
|
|
tilt_right *= tilt.tilt_yaw_angle / 90.0f;
|
|
}
|
|
|
|
// reduce authority of bicopter as motors are tilted forwards
|
|
const float scaling = cosf(tilt.current_tilt * M_PI_2);
|
|
tilt_left *= scaling;
|
|
tilt_right *= scaling;
|
|
|
|
// add current tilt and constrain
|
|
tilt_left = constrain_float(-(tilt.current_tilt * SERVO_MAX) + tilt_left, -SERVO_MAX, SERVO_MAX);
|
|
tilt_right = constrain_float(-(tilt.current_tilt * SERVO_MAX) + tilt_right, -SERVO_MAX, SERVO_MAX);
|
|
|
|
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, tilt_left);
|
|
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, tilt_right);
|
|
}
|