ardupilot/ArduPlane/Attitude.cpp

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#include "Plane.h"
/*
calculate speed scaling number for control surfaces. This is applied
to PIDs to change the scaling of the PID with speed. At high speed
we move the surfaces less, and at low speeds we move them more.
*/
float Plane::calc_speed_scaler(void)
{
float aspeed, speed_scaler;
if (ahrs.airspeed_estimate(aspeed)) {
if (aspeed > auto_state.highest_airspeed && arming.is_armed_and_safety_off()) {
auto_state.highest_airspeed = aspeed;
}
// ensure we have scaling over the full configured airspeed
const float airspeed_min = MAX(aparm.airspeed_min, MIN_AIRSPEED_MIN);
const float scale_min = MIN(0.5, g.scaling_speed / (2.0 * aparm.airspeed_max));
const float scale_max = MAX(2.0, g.scaling_speed / (0.7 * airspeed_min));
if (aspeed > 0.0001f) {
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speed_scaler = g.scaling_speed / aspeed;
} else {
speed_scaler = scale_max;
}
speed_scaler = constrain_float(speed_scaler, scale_min, scale_max);
#if HAL_QUADPLANE_ENABLED
if (quadplane.in_vtol_mode() && arming.is_armed_and_safety_off()) {
// when in VTOL modes limit surface movement at low speed to prevent instability
float threshold = airspeed_min * 0.5;
if (aspeed < threshold) {
float new_scaler = linear_interpolate(0.001, g.scaling_speed / threshold, aspeed, 0, threshold);
speed_scaler = MIN(speed_scaler, new_scaler);
// we also decay the integrator to prevent an integrator from before
// we were at low speed persistent at high speed
rollController.decay_I();
pitchController.decay_I();
yawController.decay_I();
}
}
#endif
} else if (arming.is_armed_and_safety_off()) {
// scale assumed surface movement using throttle output
float throttle_out = MAX(SRV_Channels::get_output_scaled(SRV_Channel::k_throttle), 1);
speed_scaler = sqrtf(THROTTLE_CRUISE / throttle_out);
// This case is constrained tighter as we don't have real speed info
speed_scaler = constrain_float(speed_scaler, 0.6f, 1.67f);
} else {
// no speed estimate and not armed, use a unit scaling
speed_scaler = 1;
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}
if (!plane.ahrs.using_airspeed_sensor() &&
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(plane.flight_option_enabled(FlightOptions::SURPRESS_TKOFF_SCALING)) &&
(plane.flight_stage == AP_FixedWing::FlightStage::TAKEOFF)) { //scaling is suppressed during climb phase of automatic takeoffs with no airspeed sensor being used due to problems with inaccurate airspeed estimates
return MIN(speed_scaler, 1.0f) ;
}
return speed_scaler;
}
/*
return true if the current settings and mode should allow for stick mixing
*/
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bool Plane::stick_mixing_enabled(void)
{
if (!rc().has_valid_input()) {
// never stick mix without valid RC
return false;
}
#if AP_FENCE_ENABLED
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const bool stickmixing = fence_stickmixing();
#else
const bool stickmixing = true;
#endif
#if HAL_QUADPLANE_ENABLED
if (control_mode == &mode_qrtl &&
quadplane.poscontrol.get_state() >= QuadPlane::QPOS_POSITION1) {
// user may be repositioning
return false;
}
if (quadplane.in_vtol_land_poscontrol()) {
// user may be repositioning
return false;
}
#endif
if (control_mode->does_auto_throttle() && plane.control_mode->does_auto_navigation()) {
// we're in an auto mode. Check the stick mixing flag
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if (g.stick_mixing != StickMixing::NONE &&
g.stick_mixing != StickMixing::VTOL_YAW &&
stickmixing) {
return true;
} else {
return false;
}
}
if (failsafe.rc_failsafe && g.fs_action_short == FS_ACTION_SHORT_FBWA) {
// don't do stick mixing in FBWA glide mode
return false;
}
// non-auto mode. Always do stick mixing
return true;
}
/*
this is the main roll stabilization function. It takes the
previously set nav_roll calculates roll servo_out to try to
stabilize the plane at the given roll
*/
void Plane::stabilize_roll()
{
if (fly_inverted()) {
// we want to fly upside down. We need to cope with wrap of
// the roll_sensor interfering with wrap of nav_roll, which
// would really confuse the PID code. The easiest way to
// handle this is to ensure both go in the same direction from
// zero
nav_roll_cd += 18000;
if (ahrs.roll_sensor < 0) nav_roll_cd -= 36000;
}
const float roll_out = stabilize_roll_get_roll_out();
SRV_Channels::set_output_scaled(SRV_Channel::k_aileron, roll_out);
}
float Plane::stabilize_roll_get_roll_out()
{
const float speed_scaler = get_speed_scaler();
#if HAL_QUADPLANE_ENABLED
if (!quadplane.use_fw_attitude_controllers()) {
// use the VTOL rate for control, to ensure consistency
const auto &pid_info = quadplane.attitude_control->get_rate_roll_pid().get_pid_info();
// scale FF to angle P
if (quadplane.option_is_set(QuadPlane::OPTION::SCALE_FF_ANGLE_P)) {
const float mc_angR = quadplane.attitude_control->get_angle_roll_p().kP()
* quadplane.attitude_control->get_last_angle_P_scale().x;
if (is_positive(mc_angR)) {
rollController.set_ff_scale(MIN(1.0, 1.0 / (mc_angR * rollController.tau())));
}
}
const float roll_out = rollController.get_rate_out(degrees(pid_info.target), speed_scaler);
/* when slaving fixed wing control to VTOL control we need to decay the integrator to prevent
opposing integrators balancing between the two controllers
*/
rollController.decay_I();
return roll_out;
}
#endif
bool disable_integrator = false;
if (control_mode == &mode_stabilize && channel_roll->get_control_in() != 0) {
disable_integrator = true;
}
return rollController.get_servo_out(nav_roll_cd - ahrs.roll_sensor, speed_scaler, disable_integrator,
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ground_mode && !(plane.flight_option_enabled(FlightOptions::DISABLE_GROUND_PID_SUPPRESSION)));
}
/*
this is the main pitch stabilization function. It takes the
previously set nav_pitch and calculates servo_out values to try to
stabilize the plane at the given attitude.
*/
void Plane::stabilize_pitch()
{
int8_t force_elevator = takeoff_tail_hold();
if (force_elevator != 0) {
// we are holding the tail down during takeoff. Just convert
// from a percentage to a -4500..4500 centidegree angle
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SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, 45*force_elevator);
return;
}
const float pitch_out = stabilize_pitch_get_pitch_out();
SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, pitch_out);
}
float Plane::stabilize_pitch_get_pitch_out()
{
const float speed_scaler = get_speed_scaler();
#if HAL_QUADPLANE_ENABLED
if (!quadplane.use_fw_attitude_controllers()) {
// use the VTOL rate for control, to ensure consistency
const auto &pid_info = quadplane.attitude_control->get_rate_pitch_pid().get_pid_info();
// scale FF to angle P
if (quadplane.option_is_set(QuadPlane::OPTION::SCALE_FF_ANGLE_P)) {
const float mc_angP = quadplane.attitude_control->get_angle_pitch_p().kP()
* quadplane.attitude_control->get_last_angle_P_scale().y;
if (is_positive(mc_angP)) {
pitchController.set_ff_scale(MIN(1.0, 1.0 / (mc_angP * pitchController.tau())));
}
}
const int32_t pitch_out = pitchController.get_rate_out(degrees(pid_info.target), speed_scaler);
/* when slaving fixed wing control to VTOL control we need to decay the integrator to prevent
opposing integrators balancing between the two controllers
*/
pitchController.decay_I();
return pitch_out;
}
#endif
// if LANDING_FLARE RCx_OPTION switch is set and in FW mode, manual throttle,throttle idle then set pitch to LAND_PITCH_DEG if flight option FORCE_FLARE_ATTITUDE is set
#if HAL_QUADPLANE_ENABLED
const bool quadplane_in_transition = quadplane.in_transition();
#else
const bool quadplane_in_transition = false;
#endif
int32_t demanded_pitch = nav_pitch_cd + int32_t(g.pitch_trim * 100.0) + SRV_Channels::get_output_scaled(SRV_Channel::k_throttle) * g.kff_throttle_to_pitch;
bool disable_integrator = false;
if (control_mode == &mode_stabilize && channel_pitch->get_control_in() != 0) {
disable_integrator = true;
}
/* force landing pitch if:
- flare switch high
- throttle stick at zero thrust
- in fixed wing non auto-throttle mode
*/
if (!quadplane_in_transition &&
!control_mode->is_vtol_mode() &&
!control_mode->does_auto_throttle() &&
flare_mode == FlareMode::ENABLED_PITCH_TARGET &&
throttle_at_zero()) {
demanded_pitch = landing.get_pitch_cd();
}
return pitchController.get_servo_out(demanded_pitch - ahrs.pitch_sensor, speed_scaler, disable_integrator,
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ground_mode && !(plane.flight_option_enabled(FlightOptions::DISABLE_GROUND_PID_SUPPRESSION)));
}
/*
this gives the user control of the aircraft in stabilization modes, only used in Stabilize Mode
to be moved to mode_stabilize.cpp in future
*/
void ModeStabilize::stabilize_stick_mixing_direct()
{
if (!plane.stick_mixing_enabled()) {
return;
}
#if HAL_QUADPLANE_ENABLED
if (!plane.quadplane.allow_stick_mixing()) {
return;
}
#endif
float aileron = SRV_Channels::get_output_scaled(SRV_Channel::k_aileron);
aileron = plane.channel_roll->stick_mixing(aileron);
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SRV_Channels::set_output_scaled(SRV_Channel::k_aileron, aileron);
float elevator = SRV_Channels::get_output_scaled(SRV_Channel::k_elevator);
elevator = plane.channel_pitch->stick_mixing(elevator);
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SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, elevator);
}
/*
this gives the user control of the aircraft in stabilization modes
using FBW style controls
*/
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void Plane::stabilize_stick_mixing_fbw()
{
if (!stick_mixing_enabled() ||
control_mode == &mode_acro ||
control_mode == &mode_fbwa ||
control_mode == &mode_autotune ||
control_mode == &mode_fbwb ||
control_mode == &mode_cruise ||
#if HAL_QUADPLANE_ENABLED
control_mode == &mode_qstabilize ||
control_mode == &mode_qhover ||
control_mode == &mode_qloiter ||
control_mode == &mode_qland ||
control_mode == &mode_qacro ||
#if QAUTOTUNE_ENABLED
control_mode == &mode_qautotune ||
#endif
!quadplane.allow_stick_mixing() ||
#endif // HAL_QUADPLANE_ENABLED
control_mode == &mode_training) {
return;
}
// do FBW style stick mixing. We don't treat it linearly
// however. For inputs up to half the maximum, we use linear
// addition to the nav_roll and nav_pitch. Above that it goes
// non-linear and ends up as 2x the maximum, to ensure that
// the user can direct the plane in any direction with stick
// mixing.
float roll_input = channel_roll->norm_input_dz();
if (roll_input > 0.5f) {
roll_input = (3*roll_input - 1);
} else if (roll_input < -0.5f) {
roll_input = (3*roll_input + 1);
}
nav_roll_cd += roll_input * roll_limit_cd;
nav_roll_cd = constrain_int32(nav_roll_cd, -roll_limit_cd, roll_limit_cd);
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if ((control_mode == &mode_loiter) && (plane.flight_option_enabled(FlightOptions::ENABLE_LOITER_ALT_CONTROL))) {
// loiter is using altitude control based on the pitch stick, don't use it again here
return;
}
float pitch_input = channel_pitch->norm_input_dz();
if (pitch_input > 0.5f) {
pitch_input = (3*pitch_input - 1);
} else if (pitch_input < -0.5f) {
pitch_input = (3*pitch_input + 1);
}
if (fly_inverted()) {
pitch_input = -pitch_input;
}
if (pitch_input > 0) {
nav_pitch_cd += pitch_input * aparm.pitch_limit_max*100;
} else {
nav_pitch_cd += -(pitch_input * pitch_limit_min*100);
}
nav_pitch_cd = constrain_int32(nav_pitch_cd, pitch_limit_min*100, aparm.pitch_limit_max.get()*100);
}
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/*
stabilize the yaw axis. There are 3 modes of operation:
- hold a specific heading with ground steering
- rate controlled with ground steering
- yaw control for coordinated flight
*/
void Plane::stabilize_yaw()
{
bool ground_steering = false;
if (landing.is_flaring()) {
// in flaring then enable ground steering
ground_steering = true;
} else {
// otherwise use ground steering when no input control and we
// are below the GROUND_STEER_ALT
ground_steering = (channel_roll->get_control_in() == 0 &&
fabsf(relative_altitude) < g.ground_steer_alt);
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if (!landing.is_ground_steering_allowed()) {
// don't use ground steering on landing approach
ground_steering = false;
}
}
/*
first calculate steering for a nose or tail
wheel. We use "course hold" mode for the rudder when either performing
a flare (when the wings are held level) or when in course hold in
FBWA mode (when we are below GROUND_STEER_ALT)
*/
float steering_output = 0.0;
if (landing.is_flaring() ||
(steer_state.hold_course_cd != -1 && ground_steering)) {
steering_output = calc_nav_yaw_course();
} else if (ground_steering) {
steering_output = calc_nav_yaw_ground();
}
/*
now calculate rudder for the rudder
*/
const float rudder_output = calc_nav_yaw_coordinated();
if (!ground_steering) {
// Not doing ground steering, output rudder on steering channel
SRV_Channels::set_output_scaled(SRV_Channel::k_rudder, rudder_output);
SRV_Channels::set_output_scaled(SRV_Channel::k_steering, rudder_output);
} else if (!SRV_Channels::function_assigned(SRV_Channel::k_steering)) {
// Ground steering active but no steering output configured, output steering on rudder channel
SRV_Channels::set_output_scaled(SRV_Channel::k_rudder, steering_output);
SRV_Channels::set_output_scaled(SRV_Channel::k_steering, steering_output);
} else {
// Ground steering with both steering and rudder channels
SRV_Channels::set_output_scaled(SRV_Channel::k_rudder, rudder_output);
SRV_Channels::set_output_scaled(SRV_Channel::k_steering, steering_output);
}
}
/*
main stabilization function for all 3 axes
*/
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void Plane::stabilize()
{
uint32_t now = AP_HAL::millis();
#if HAL_QUADPLANE_ENABLED
if (quadplane.available()) {
quadplane.transition->set_FW_roll_pitch(nav_pitch_cd, nav_roll_cd);
}
#endif
if (now - last_stabilize_ms > 2000) {
// if we haven't run the rate controllers for 2 seconds then reset
control_mode->reset_controllers();
}
last_stabilize_ms = now;
if (control_mode == &mode_training ||
control_mode == &mode_manual) {
plane.control_mode->run();
#if AP_SCRIPTING_ENABLED
} else if (nav_scripting_active()) {
// scripting is in control of roll and pitch rates and throttle
const float speed_scaler = get_speed_scaler();
const float aileron = rollController.get_rate_out(nav_scripting.roll_rate_dps, speed_scaler);
const float elevator = pitchController.get_rate_out(nav_scripting.pitch_rate_dps, speed_scaler);
SRV_Channels::set_output_scaled(SRV_Channel::k_aileron, aileron);
SRV_Channels::set_output_scaled(SRV_Channel::k_elevator, elevator);
float rudder = 0;
if (yawController.rate_control_enabled()) {
rudder = nav_scripting.rudder_offset_pct * 45;
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if (nav_scripting.run_yaw_rate_controller) {
rudder += yawController.get_rate_out(nav_scripting.yaw_rate_dps, speed_scaler, false);
} else {
yawController.reset_I();
}
}
SRV_Channels::set_output_scaled(SRV_Channel::k_rudder, rudder);
SRV_Channels::set_output_scaled(SRV_Channel::k_steering, rudder);
SRV_Channels::set_output_scaled(SRV_Channel::k_throttle, plane.nav_scripting.throttle_pct);
#endif
} else {
plane.control_mode->run();
}
/*
see if we should zero the attitude controller integrators.
*/
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if (is_zero(get_throttle_input()) &&
fabsf(relative_altitude) < 5.0f &&
fabsf(barometer.get_climb_rate()) < 0.5f &&
ahrs.groundspeed() < 3) {
// we are low, with no climb rate, and zero throttle, and very
// low ground speed. Zero the attitude controller
// integrators. This prevents integrator buildup pre-takeoff.
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rollController.reset_I();
pitchController.reset_I();
yawController.reset_I();
// if moving very slowly also zero the steering integrator
if (ahrs.groundspeed() < 1) {
steerController.reset_I();
}
}
}
/*
* Set the throttle output.
* This is called by TECS-enabled flight modes, e.g. AUTO, GUIDED, etc.
*/
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void Plane::calc_throttle()
{
if (aparm.throttle_cruise <= 1) {
// user has asked for zero throttle - this may be done by a
// mission which wants to turn off the engine for a parachute
// landing
SRV_Channels::set_output_scaled(SRV_Channel::k_throttle, 0.0);
return;
}
// Read the TECS throttle output and set it to the throttle channel.
float commanded_throttle = TECS_controller.get_throttle_demand();
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SRV_Channels::set_output_scaled(SRV_Channel::k_throttle, commanded_throttle);
}
/*****************************************
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* Calculate desired roll/pitch/yaw angles (in medium freq loop)
*****************************************/
/*
calculate yaw control for coordinated flight
*/
int16_t Plane::calc_nav_yaw_coordinated()
{
const float speed_scaler = get_speed_scaler();
bool disable_integrator = false;
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int16_t rudder_in = rudder_input();
int16_t commanded_rudder;
bool using_rate_controller = false;
// Received an external msg that guides yaw in the last 3 seconds?
if (control_mode->is_guided_mode() &&
plane.guided_state.last_forced_rpy_ms.z > 0 &&
millis() - plane.guided_state.last_forced_rpy_ms.z < 3000) {
commanded_rudder = plane.guided_state.forced_rpy_cd.z;
} else if (autotuning && g.acro_yaw_rate > 0 && yawController.rate_control_enabled()) {
// user is doing an AUTOTUNE with yaw rate control
const float rudd_expo = rudder_in_expo(true);
const float yaw_rate = (rudd_expo/SERVO_MAX) * g.acro_yaw_rate;
// add in the coordinated turn yaw rate to make it easier to fly while tuning the yaw rate controller
const float coordination_yaw_rate = degrees(GRAVITY_MSS * tanf(radians(nav_roll_cd*0.01f))/MAX(aparm.airspeed_min,smoothed_airspeed));
commanded_rudder = yawController.get_rate_out(yaw_rate+coordination_yaw_rate, speed_scaler, false);
using_rate_controller = true;
} else {
if (control_mode == &mode_stabilize && rudder_in != 0) {
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disable_integrator = true;
}
commanded_rudder = yawController.get_servo_out(speed_scaler, disable_integrator);
// add in rudder mixing from roll
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commanded_rudder += SRV_Channels::get_output_scaled(SRV_Channel::k_aileron) * g.kff_rudder_mix;
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commanded_rudder += rudder_in;
}
if (!using_rate_controller) {
/*
When not running the yaw rate controller, we need to reset the rate
*/
yawController.reset_rate_PID();
}
return constrain_int16(commanded_rudder, -4500, 4500);
}
/*
calculate yaw control for ground steering with specific course
*/
int16_t Plane::calc_nav_yaw_course(void)
{
// holding a specific navigation course on the ground. Used in
// auto-takeoff and landing
int32_t bearing_error_cd = nav_controller->bearing_error_cd();
int16_t steering = steerController.get_steering_out_angle_error(bearing_error_cd);
if (stick_mixing_enabled()) {
steering = channel_rudder->stick_mixing(steering);
}
return constrain_int16(steering, -4500, 4500);
}
/*
calculate yaw control for ground steering
*/
int16_t Plane::calc_nav_yaw_ground(void)
{
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if (gps.ground_speed() < 1 &&
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is_zero(get_throttle_input()) &&
flight_stage != AP_FixedWing::FlightStage::TAKEOFF &&
flight_stage != AP_FixedWing::FlightStage::ABORT_LANDING) {
// manual rudder control while still
steer_state.locked_course = false;
steer_state.locked_course_err = 0;
return rudder_input();
}
// if we haven't been steering for 1s then clear locked course
const uint32_t now_ms = AP_HAL::millis();
if (now_ms - steer_state.last_steer_ms > 1000) {
steer_state.locked_course = false;
}
steer_state.last_steer_ms = now_ms;
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float steer_rate = (rudder_input()/4500.0f) * g.ground_steer_dps;
if (flight_stage == AP_FixedWing::FlightStage::TAKEOFF ||
flight_stage == AP_FixedWing::FlightStage::ABORT_LANDING) {
steer_rate = 0;
}
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if (!is_zero(steer_rate)) {
// pilot is giving rudder input
steer_state.locked_course = false;
} else if (!steer_state.locked_course) {
// pilot has released the rudder stick or we are still - lock the course
steer_state.locked_course = true;
if (flight_stage != AP_FixedWing::FlightStage::TAKEOFF &&
flight_stage != AP_FixedWing::FlightStage::ABORT_LANDING) {
steer_state.locked_course_err = 0;
}
}
int16_t steering;
if (!steer_state.locked_course) {
// use a rate controller at the pilot specified rate
steering = steerController.get_steering_out_rate(steer_rate);
} else {
// use a error controller on the summed error
int32_t yaw_error_cd = -ToDeg(steer_state.locked_course_err)*100;
steering = steerController.get_steering_out_angle_error(yaw_error_cd);
}
return constrain_int16(steering, -4500, 4500);
}
/*
calculate a new nav_pitch_cd from the speed height controller
*/
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void Plane::calc_nav_pitch()
{
int32_t commanded_pitch = TECS_controller.get_pitch_demand();
nav_pitch_cd = constrain_int32(commanded_pitch, pitch_limit_min*100, aparm.pitch_limit_max.get()*100);
}
/*
calculate a new nav_roll_cd from the navigation controller
*/
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void Plane::calc_nav_roll()
{
int32_t commanded_roll = nav_controller->nav_roll_cd();
nav_roll_cd = constrain_int32(commanded_roll, -roll_limit_cd, roll_limit_cd);
update_load_factor();
}
/*
adjust nav_pitch_cd for STAB_PITCH_DOWN_CD. This is used to make
keeping up good airspeed in FBWA mode easier, as the plane will
automatically pitch down a little when at low throttle. It makes
FBWA landings without stalling much easier.
*/
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void Plane::adjust_nav_pitch_throttle(void)
{
int8_t throttle = throttle_percentage();
if (throttle >= 0 && throttle < aparm.throttle_cruise && flight_stage != AP_FixedWing::FlightStage::VTOL) {
float p = (aparm.throttle_cruise - throttle) / (float)aparm.throttle_cruise;
nav_pitch_cd -= g.stab_pitch_down * 100.0f * p;
}
}
/*
calculate a new aerodynamic_load_factor and limit nav_roll_cd to
ensure that the load factor does not take us below the sustainable
airspeed
*/
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void Plane::update_load_factor(void)
{
float demanded_roll = fabsf(nav_roll_cd*0.01f);
if (demanded_roll > 85) {
// limit to 85 degrees to prevent numerical errors
demanded_roll = 85;
}
aerodynamic_load_factor = 1.0f / safe_sqrt(cosf(radians(demanded_roll)));
#if HAL_QUADPLANE_ENABLED
if (quadplane.available() && quadplane.transition->set_FW_roll_limit(roll_limit_cd)) {
nav_roll_cd = constrain_int32(nav_roll_cd, -roll_limit_cd, roll_limit_cd);
return;
}
#endif
if (!aparm.stall_prevention) {
// stall prevention is disabled
return;
}
if (fly_inverted()) {
// no roll limits when inverted
return;
}
#if HAL_QUADPLANE_ENABLED
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if (quadplane.tailsitter.active()) {
// no limits while hovering
return;
}
#endif
float max_load_factor = smoothed_airspeed / MAX(aparm.airspeed_min, 1);
if (max_load_factor <= 1) {
// our airspeed is below the minimum airspeed. Limit roll to
// 25 degrees
nav_roll_cd = constrain_int32(nav_roll_cd, -2500, 2500);
roll_limit_cd = MIN(roll_limit_cd, 2500);
} else if (max_load_factor < aerodynamic_load_factor) {
// the demanded nav_roll would take us past the aerodynamic
// load limit. Limit our roll to a bank angle that will keep
// the load within what the airframe can handle. We always
// allow at least 25 degrees of roll however, to ensure the
// aircraft can be manoeuvred with a bad airspeed estimate. At
// 25 degrees the load factor is 1.1 (10%)
int32_t roll_limit = degrees(acosf(sq(1.0f / max_load_factor)))*100;
if (roll_limit < 2500) {
roll_limit = 2500;
}
nav_roll_cd = constrain_int32(nav_roll_cd, -roll_limit, roll_limit);
roll_limit_cd = MIN(roll_limit_cd, roll_limit);
}
}