ardupilot/ArduPlane/tiltrotor.cpp

771 lines
31 KiB
C++

#include "tiltrotor.h"
#include "Plane.h"
#if HAL_QUADPLANE_ENABLED
const AP_Param::GroupInfo Tiltrotor::var_info[] = {
// @Param: ENABLE
// @DisplayName: Enable Tiltrotor functionality
// @Values: 0:Disable, 1:Enable
// @Description: This enables Tiltrotor functionality
// @User: Standard
// @RebootRequired: True
AP_GROUPINFO_FLAGS("ENABLE", 1, Tiltrotor, enable, 0, AP_PARAM_FLAG_ENABLE),
// @Param: MASK
// @DisplayName: Tiltrotor mask
// @Description: This is a bitmask of motors that are tiltable in a tiltrotor (or tiltwing). The mask is in terms of the standard motor order for the frame type.
// @User: Standard
// @Bitmask: 0:Motor 1, 1:Motor 2, 2:Motor 3, 3:Motor 4, 4:Motor 5, 5:Motor 6, 6:Motor 7, 7:Motor 8, 8:Motor 9, 9:Motor 10, 10:Motor 11, 11:Motor 12
AP_GROUPINFO("MASK", 2, Tiltrotor, tilt_mask, 0),
// @Param: RATE_UP
// @DisplayName: Tiltrotor upwards tilt rate
// @Description: This is the maximum speed at which the motor angle will change for a tiltrotor when moving from forward flight to hover
// @Units: deg/s
// @Increment: 1
// @Range: 10 300
// @User: Standard
AP_GROUPINFO("RATE_UP", 3, Tiltrotor, max_rate_up_dps, 40),
// @Param: MAX
// @DisplayName: Tiltrotor maximum VTOL angle
// @Description: This is the maximum angle of the tiltable motors at which multicopter control will be enabled. Beyond this angle the plane will fly solely as a fixed wing aircraft and the motors will tilt to their maximum angle at the TILT_RATE
// @Units: deg
// @Increment: 1
// @Range: 20 80
// @User: Standard
AP_GROUPINFO("MAX", 4, Tiltrotor, max_angle_deg, 45),
// @Param: TYPE
// @DisplayName: Tiltrotor type
// @Description: This is the type of tiltrotor when TILT_MASK is non-zero. A continuous tiltrotor can tilt the rotors to any angle on demand. A binary tiltrotor assumes a retract style servo where the servo is either fully forward or fully up. In both cases the servo can't move faster than Q_TILT_RATE. A vectored yaw tiltrotor will use the tilt of the motors to control yaw in hover, Bicopter tiltrotor must use the tailsitter frame class (10)
// @Values: 0:Continuous,1:Binary,2:VectoredYaw,3:Bicopter
AP_GROUPINFO("TYPE", 5, Tiltrotor, type, TILT_TYPE_CONTINUOUS),
// @Param: RATE_DN
// @DisplayName: Tiltrotor downwards tilt rate
// @Description: This is the maximum speed at which the motor angle will change for a tiltrotor when moving from hover to forward flight. When this is zero the Q_TILT_RATE_UP value is used.
// @Units: deg/s
// @Increment: 1
// @Range: 10 300
// @User: Standard
AP_GROUPINFO("RATE_DN", 6, Tiltrotor, max_rate_down_dps, 0),
// @Param: YAW_ANGLE
// @DisplayName: Tilt minimum angle for vectored yaw
// @Description: This is the angle of the tilt servos when in VTOL mode and at minimum output (fully back). This needs to be set in addition to Q_TILT_TYPE=2, to enable vectored control for yaw in tilt quadplanes. This is also used to limit the forward travel of bicopter tilts(Q_TILT_TYPE=3) when in VTOL modes.
// @Range: 0 30
AP_GROUPINFO("YAW_ANGLE", 7, Tiltrotor, tilt_yaw_angle, 0),
// @Param: FIX_ANGLE
// @DisplayName: Fixed wing tiltrotor angle
// @Description: This is the angle the motors tilt down when at maximum output for forward flight. Set this to a non-zero value to enable vectoring for roll/pitch in forward flight on tilt-vectored aircraft
// @Units: deg
// @Range: 0 30
// @User: Standard
AP_GROUPINFO("FIX_ANGLE", 8, Tiltrotor, fixed_angle, 0),
// @Param: FIX_GAIN
// @DisplayName: Fixed wing tiltrotor gain
// @Description: This is the gain for use of tilting motors in fixed wing flight for tilt vectored quadplanes
// @Range: 0 1
// @User: Standard
AP_GROUPINFO("FIX_GAIN", 9, Tiltrotor, fixed_gain, 0),
// @Param: WING_FLAP
// @DisplayName: Tiltrotor tilt angle that will be used as flap
// @Description: For use on tilt wings, the wing will tilt up to this angle for flap, transition will be complete when the wing reaches this angle from the forward fight position, 0 disables
// @Units: deg
// @Increment: 1
// @Range: 0 15
// @User: Standard
AP_GROUPINFO("WING_FLAP", 10, Tiltrotor, flap_angle_deg, 0),
AP_GROUPEND
};
/*
control code for tiltrotors and tiltwings. Enabled by setting
Q_TILT_MASK to a non-zero value
*/
Tiltrotor::Tiltrotor(QuadPlane& _quadplane, AP_MotorsMulticopter*& _motors):quadplane(_quadplane),motors(_motors)
{
AP_Param::setup_object_defaults(this, var_info);
}
void Tiltrotor::setup()
{
if (!enable.configured() && ((tilt_mask != 0) || (type == TILT_TYPE_BICOPTER))) {
enable.set_and_save(1);
}
if (enable <= 0) {
return;
}
_is_vectored = tilt_mask != 0 && type == TILT_TYPE_VECTORED_YAW;
// true if a fixed forward motor is configured, either throttle, throttle left or throttle right.
// bicopter tiltrotors use throttle left and right as tilting motors, so they don't count in that case.
_have_fw_motor = SRV_Channels::function_assigned(SRV_Channel::k_throttle) ||
((SRV_Channels::function_assigned(SRV_Channel::k_throttleLeft) || SRV_Channels::function_assigned(SRV_Channel::k_throttleRight))
&& (type != TILT_TYPE_BICOPTER));
// check if there are any permanent VTOL motors
for (uint8_t i = 0; i < AP_MOTORS_MAX_NUM_MOTORS; ++i) {
if (motors->is_motor_enabled(i) && ((tilt_mask & (1U<<1)) == 0)) {
// enabled motor not set in tilt mask
_have_vtol_motor = true;
break;
}
}
if (_is_vectored) {
// we will be using vectoring for yaw
motors->disable_yaw_torque();
}
if (tilt_mask != 0) {
// setup tilt compensation
motors->set_thrust_compensation_callback(FUNCTOR_BIND_MEMBER(&Tiltrotor::tilt_compensate, void, float *, uint8_t));
if (type == TILT_TYPE_VECTORED_YAW) {
// setup tilt servos for vectored yaw
SRV_Channels::set_range(SRV_Channel::k_tiltMotorLeft, 1000);
SRV_Channels::set_range(SRV_Channel::k_tiltMotorRight, 1000);
SRV_Channels::set_range(SRV_Channel::k_tiltMotorRear, 1000);
SRV_Channels::set_range(SRV_Channel::k_tiltMotorRearLeft, 1000);
SRV_Channels::set_range(SRV_Channel::k_tiltMotorRearRight, 1000);
}
}
transition = NEW_NOTHROW Tiltrotor_Transition(quadplane, motors, *this);
if (!transition) {
AP_BoardConfig::allocation_error("tiltrotor transition");
}
quadplane.transition = transition;
setup_complete = true;
}
/*
calculate maximum tilt change as a proportion from 0 to 1 of tilt
*/
float Tiltrotor::tilt_max_change(bool up, bool in_flap_range) const
{
float rate;
if (up || max_rate_down_dps <= 0) {
rate = max_rate_up_dps;
} else {
rate = max_rate_down_dps;
}
if (type != TILT_TYPE_BINARY && !up && !in_flap_range) {
bool fast_tilt = false;
if (plane.control_mode == &plane.mode_manual) {
fast_tilt = true;
}
if (plane.arming.is_armed_and_safety_off() && !quadplane.in_vtol_mode() && !quadplane.assisted_flight) {
fast_tilt = true;
}
if (fast_tilt) {
// allow a minimum of 90 DPS in manual or if we are not
// stabilising, to give fast control
rate = MAX(rate, 90);
}
}
return rate * plane.G_Dt * (1/90.0);
}
/*
output a slew limited tiltrotor angle. tilt is from 0 to 1
*/
void Tiltrotor::slew(float newtilt)
{
float max_change = tilt_max_change(newtilt<current_tilt, newtilt > get_fully_forward_tilt());
current_tilt = constrain_float(newtilt, current_tilt-max_change, current_tilt+max_change);
angle_achieved = is_equal(newtilt, current_tilt);
// translate to 0..1000 range and output
SRV_Channels::set_output_scaled(SRV_Channel::k_motor_tilt, 1000 * current_tilt);
}
// return the current tilt value that represents forward flight
// tilt wings can sustain forward flight with some amount of wing tilt
float Tiltrotor::get_fully_forward_tilt() const
{
return 1.0 - (flap_angle_deg * (1/90.0));
}
// return the target tilt value for forward flight
float Tiltrotor::get_forward_flight_tilt() const
{
return 1.0 - ((flap_angle_deg * (1/90.0)) * SRV_Channels::get_slew_limited_output_scaled(SRV_Channel::k_flap_auto) * 0.01);
}
/*
update motor tilt for continuous tilt servos
*/
void Tiltrotor::continuous_update(void)
{
// default to inactive
_motors_active = false;
// the maximum rate of throttle change
float max_change;
if (!quadplane.in_vtol_mode() && (!plane.arming.is_armed_and_safety_off() || !quadplane.assisted_flight)) {
// we are in pure fixed wing mode. Move the tiltable motors all the way forward and run them as
// a forward motor
// option set then if disarmed move to VTOL position to prevent ground strikes, allow tilt forward in manual mode for testing
const bool disarmed_tilt_up = !plane.arming.is_armed_and_safety_off() && (plane.control_mode != &plane.mode_manual) && quadplane.option_is_set(QuadPlane::OPTION::DISARMED_TILT_UP);
slew(disarmed_tilt_up ? 0.0 : get_forward_flight_tilt());
max_change = tilt_max_change(false);
float new_throttle = constrain_float(SRV_Channels::get_output_scaled(SRV_Channel::k_throttle)*0.01, 0, 1);
if (current_tilt < get_fully_forward_tilt()) {
current_throttle = constrain_float(new_throttle,
current_throttle-max_change,
current_throttle+max_change);
} else {
current_throttle = new_throttle;
}
if (!plane.arming.is_armed_and_safety_off()) {
current_throttle = 0;
} else {
// prevent motor shutdown
_motors_active = true;
}
if (!quadplane.motor_test.running) {
// the motors are all the way forward, start using them for fwd thrust
const uint16_t mask = is_zero(current_throttle)?0U:tilt_mask.get();
motors->output_motor_mask(current_throttle, mask, plane.rudder_dt);
}
return;
}
// remember the throttle level we're using for VTOL flight
float motors_throttle = motors->get_throttle();
max_change = tilt_max_change(motors_throttle<current_throttle);
current_throttle = constrain_float(motors_throttle,
current_throttle-max_change,
current_throttle+max_change);
/*
we are in a VTOL mode. We need to work out how much tilt is
needed. There are 5 strategies we will use:
1) With use of a forward throttle controlled by Q_FWD_THR_GAIN in
VTOL modes except Q_AUTOTUNE determined by Q_FWD_THR_USE. We set the angle based on a calculated
forward throttle.
2) With manual forward throttle control we set the angle based on the
RC input demanded forward throttle for QACRO, QSTABILIZE and QHOVER.
3) Without a RC input or calculated forward throttle value, the angle
will be set to zero in QAUTOTUNE, QACRO, QSTABILIZE and QHOVER.
This enables these modes to be used as a safe recovery mode.
4) In fixed wing assisted flight or velocity controlled modes we will
set the angle based on the demanded forward throttle, with a maximum
tilt given by Q_TILT_MAX. This relies on Q_FWD_THR_GAIN or Q_VFWD_GAIN
being set.
5) if we are in TRANSITION_TIMER mode then we are transitioning
to forward flight and should put the rotors all the way forward
*/
#if QAUTOTUNE_ENABLED
if (plane.control_mode == &plane.mode_qautotune) {
slew(0);
return;
}
#endif
if (!quadplane.assisted_flight &&
quadplane.get_vfwd_method() == QuadPlane::ActiveFwdThr::NEW &&
quadplane.is_flying_vtol())
{
// We are using the rotor tilt functionality controlled by Q_FWD_THR_GAIN which can
// operate in all VTOL modes except Q_AUTOTUNE. Forward rotor tilt is used to produce
// forward thrust equivalent to what would have been produced by a forward thrust motor
// set to quadplane.forward_throttle_pct()
const float fwd_g_demand = 0.01 * quadplane.forward_throttle_pct();
const float fwd_tilt_deg = MIN(degrees(atanf(fwd_g_demand)), (float)max_angle_deg);
slew(MIN(fwd_tilt_deg * (1/90.0), get_forward_flight_tilt()));
return;
} else if (!quadplane.assisted_flight &&
(plane.control_mode == &plane.mode_qacro ||
plane.control_mode == &plane.mode_qstabilize ||
plane.control_mode == &plane.mode_qhover))
{
if (quadplane.rc_fwd_thr_ch == nullptr) {
// no manual throttle control, set angle to zero
slew(0);
} else {
// manual control of forward throttle up to max VTOL angle
float settilt = .01f * quadplane.forward_throttle_pct();
slew(MIN(settilt * max_angle_deg * (1/90.0), get_forward_flight_tilt()));
}
return;
}
if (quadplane.assisted_flight &&
transition->transition_state >= Tiltrotor_Transition::TRANSITION_TIMER) {
// we are transitioning to fixed wing - tilt the motors all
// the way forward
slew(get_forward_flight_tilt());
} else {
// until we have completed the transition we limit the tilt to
// Q_TILT_MAX. Anything above 50% throttle gets
// Q_TILT_MAX. Below 50% throttle we decrease linearly. This
// relies heavily on Q_VFWD_GAIN being set appropriately.
float settilt = constrain_float((SRV_Channels::get_output_scaled(SRV_Channel::k_throttle)-MAX(plane.aparm.throttle_min.get(),0)) * 0.02, 0, 1);
slew(MIN(settilt * max_angle_deg * (1/90.0), get_forward_flight_tilt()));
}
}
/*
output a slew limited tiltrotor angle. tilt is 0 or 1
*/
void Tiltrotor::binary_slew(bool forward)
{
// The servo output is binary, not slew rate limited
SRV_Channels::set_output_scaled(SRV_Channel::k_motor_tilt, forward?1000:0);
// rate limiting current_tilt has the effect of delaying throttle in tiltrotor_binary_update
float max_change = tilt_max_change(!forward);
if (forward) {
current_tilt = constrain_float(current_tilt+max_change, 0, 1);
} else {
current_tilt = constrain_float(current_tilt-max_change, 0, 1);
}
}
/*
update motor tilt for binary tilt servos
*/
void Tiltrotor::binary_update(void)
{
// motors always active
_motors_active = true;
if (!quadplane.in_vtol_mode()) {
// we are in pure fixed wing mode. Move the tiltable motors
// all the way forward and run them as a forward motor
binary_slew(true);
float new_throttle = SRV_Channels::get_output_scaled(SRV_Channel::k_throttle)*0.01f;
if (current_tilt >= 1) {
const uint16_t mask = is_zero(new_throttle)?0U:tilt_mask.get();
// the motors are all the way forward, start using them for fwd thrust
motors->output_motor_mask(new_throttle, mask, plane.rudder_dt);
}
} else {
binary_slew(false);
}
}
/*
update motor tilt
*/
void Tiltrotor::update(void)
{
if (!enabled() || tilt_mask == 0) {
// no motors to tilt
return;
}
if (type == TILT_TYPE_BINARY) {
binary_update();
} else {
continuous_update();
}
if (type == TILT_TYPE_VECTORED_YAW) {
vectoring();
}
}
#if HAL_LOGGING_ENABLED
// Write tiltrotor specific log
void Tiltrotor::write_log()
{
struct log_tiltrotor pkt {
LOG_PACKET_HEADER_INIT(LOG_TILT_MSG),
time_us : AP_HAL::micros64(),
current_tilt : current_tilt * 90.0,
};
if (type != TILT_TYPE_VECTORED_YAW) {
// Left and right tilt are invalid
pkt.front_left_tilt = plane.logger.quiet_nanf();
pkt.front_right_tilt = plane.logger.quiet_nanf();
} else {
// Calculate tilt angle from servo outputs
const float total_angle = 90.0 + tilt_yaw_angle + fixed_angle;
const float scale = total_angle * 0.001;
pkt.front_left_tilt = (SRV_Channels::get_output_scaled(SRV_Channel::k_tiltMotorLeft) * scale) - tilt_yaw_angle;
pkt.front_right_tilt = (SRV_Channels::get_output_scaled(SRV_Channel::k_tiltMotorRight) * scale) - tilt_yaw_angle;
}
plane.logger.WriteBlock(&pkt, sizeof(pkt));
}
#endif
/*
tilt compensation for angle of tilt. When the rotors are tilted the
roll effect of differential thrust on the tilted rotors is decreased
and the yaw effect increased
We have two factors we apply.
1) when we are transitioning to fwd flight we scale the tilted rotors by 1/cos(angle). This pushes us towards more flight speed
2) when we are transitioning to hover we scale the non-tilted rotors by cos(angle). This pushes us towards lower fwd thrust
We also apply an equalisation to the tilted motors in proportion to
how much tilt we have. This smoothly reduces the impact of the roll
gains as we tilt further forward.
For yaw, we apply differential thrust in proportion to the demanded
yaw control and sin of the tilt angle
Finally we ensure no requested thrust is over 1 by scaling back all
motors so the largest thrust is at most 1.0
*/
void Tiltrotor::tilt_compensate_angle(float *thrust, uint8_t num_motors, float non_tilted_mul, float tilted_mul)
{
float tilt_total = 0;
uint8_t tilt_count = 0;
// apply tilt_factors first
for (uint8_t i=0; i<num_motors; i++) {
if (!is_motor_tilting(i)) {
thrust[i] *= non_tilted_mul;
} else {
thrust[i] *= tilted_mul;
tilt_total += thrust[i];
tilt_count++;
}
}
float largest_tilted = 0;
const float sin_tilt = sinf(radians(current_tilt*90));
// yaw_gain relates the amount of differential thrust we get from
// tilt, so that the scaling of the yaw control is the same at any
// tilt angle
const float yaw_gain = sinf(radians(tilt_yaw_angle));
const float avg_tilt_thrust = tilt_total / tilt_count;
for (uint8_t i=0; i<num_motors; i++) {
if (is_motor_tilting(i)) {
// as we tilt we need to reduce the impact of the roll
// controller. This simple method keeps the same average,
// but moves us to no roll control as the angle increases
thrust[i] = current_tilt * avg_tilt_thrust + thrust[i] * (1-current_tilt);
// add in differential thrust for yaw control, scaled by tilt angle
const float diff_thrust = motors->get_roll_factor(i) * (motors->get_yaw()+motors->get_yaw_ff()) * sin_tilt * yaw_gain;
thrust[i] += diff_thrust;
largest_tilted = MAX(largest_tilted, thrust[i]);
}
}
// if we are saturating one of the motors then reduce all motors
// to keep them in proportion to the original thrust. This helps
// maintain stability when tilted at a large angle
if (largest_tilted > 1.0f) {
float scale = 1.0f / largest_tilted;
for (uint8_t i=0; i<num_motors; i++) {
thrust[i] *= scale;
}
}
}
/*
choose up or down tilt compensation based on flight mode When going
to a fixed wing mode we use tilt_compensate_down, when going to a
VTOL mode we use tilt_compensate_up
*/
void Tiltrotor::tilt_compensate(float *thrust, uint8_t num_motors)
{
if (current_tilt <= 0) {
// the motors are not tilted, no compensation needed
return;
}
if (quadplane.in_vtol_mode()) {
// we are transitioning to VTOL flight
const float tilt_factor = cosf(radians(current_tilt*90));
tilt_compensate_angle(thrust, num_motors, tilt_factor, 1);
} else {
float inv_tilt_factor;
if (current_tilt > 0.98f) {
inv_tilt_factor = 1.0 / cosf(radians(0.98f*90));
} else {
inv_tilt_factor = 1.0 / cosf(radians(current_tilt*90));
}
tilt_compensate_angle(thrust, num_motors, 1, inv_tilt_factor);
}
}
/*
return true if the rotors are fully tilted forward
*/
bool Tiltrotor::fully_fwd(void) const
{
if (!enabled() || (tilt_mask == 0)) {
return false;
}
return (current_tilt >= get_fully_forward_tilt());
}
/*
return true if the rotors are fully tilted up
*/
bool Tiltrotor::fully_up(void) const
{
if (!enabled() || (tilt_mask == 0)) {
return false;
}
return (current_tilt <= 0);
}
/*
control vectoring for tilt multicopters
*/
void Tiltrotor::vectoring(void)
{
// total angle the tilt can go through
const float total_angle = 90 + tilt_yaw_angle + fixed_angle;
// output value (0 to 1) to get motors pointed straight up
const float zero_out = tilt_yaw_angle / total_angle;
const float fixed_tilt_limit = fixed_angle / total_angle;
const float level_out = 1.0 - fixed_tilt_limit;
// calculate the basic tilt amount from current_tilt
float base_output = zero_out + (current_tilt * (level_out - zero_out));
// for testing when disarmed, apply vectored yaw in proportion to rudder stick
// Wait TILT_DELAY_MS after disarming to allow props to spin down first.
constexpr uint32_t TILT_DELAY_MS = 3000;
uint32_t now = AP_HAL::millis();
if (!plane.arming.is_armed_and_safety_off() && plane.quadplane.option_is_set(QuadPlane::OPTION::DISARMED_TILT)) {
// this test is subject to wrapping at ~49 days, but the consequences are insignificant
if ((now - hal.util->get_last_armed_change()) > TILT_DELAY_MS) {
if (quadplane.in_vtol_mode()) {
float yaw_out = plane.channel_rudder->get_control_in();
yaw_out /= plane.channel_rudder->get_range();
float yaw_range = zero_out;
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, 1000 * constrain_float(base_output + yaw_out * yaw_range,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, 1000 * constrain_float(base_output - yaw_out * yaw_range,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft, 1000 * constrain_float(base_output + yaw_out * yaw_range,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight, 1000 * constrain_float(base_output - yaw_out * yaw_range,0,1));
} else {
// fixed wing tilt
const float gain = fixed_gain * fixed_tilt_limit;
// base the tilt on elevon mixing, which means it
// takes account of the MIXING_GAIN. The rear tilt is
// based on elevator
const float right = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_right) * (1/4500.0);
const float left = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_left) * (1/4500.0);
const float mid = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevator) * (1/4500.0);
// front tilt is effective canards, so need to swap and use negative. Rear motors are treated live elevons.
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft,1000 * constrain_float(base_output - right,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight,1000 * constrain_float(base_output - left,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft,1000 * constrain_float(base_output + left,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight,1000 * constrain_float(base_output + right,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output + mid,0,1));
}
}
return;
}
const bool no_yaw = tilt_over_max_angle();
if (no_yaw) {
// fixed wing We need to apply inverse scaling with throttle, and remove the surface speed scaling as
// we don't want tilt impacted by airspeed
const float scaler = plane.control_mode == &plane.mode_manual?1:(quadplane.FW_vector_throttle_scaling() / plane.get_speed_scaler());
const float gain = fixed_gain * fixed_tilt_limit * scaler;
const float right = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_right) * (1/4500.0);
const float left = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevon_left) * (1/4500.0);
const float mid = gain * SRV_Channels::get_output_scaled(SRV_Channel::k_elevator) * (1/4500.0);
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft,1000 * constrain_float(base_output - right,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight,1000 * constrain_float(base_output - left,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft,1000 * constrain_float(base_output + left,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight,1000 * constrain_float(base_output + right,0,1));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000 * constrain_float(base_output + mid,0,1));
} else {
const float yaw_out = motors->get_yaw()+motors->get_yaw_ff();
const float roll_out = motors->get_roll()+motors->get_roll_ff();
const float yaw_range = zero_out;
// Scaling yaw with throttle
const float throttle = motors->get_throttle_out();
const float scale_min = 0.5;
const float scale_max = 2.0;
float throttle_scaler = scale_max;
if (is_positive(throttle)) {
throttle_scaler = constrain_float(motors->get_throttle_hover() / throttle, scale_min, scale_max);
}
// now apply vectored thrust for yaw and roll.
const float tilt_rad = radians(current_tilt*90);
const float sin_tilt = sinf(tilt_rad);
const float cos_tilt = cosf(tilt_rad);
// the MotorsMatrix library normalises roll factor to 0.5, so
// we need to use the same factor here to keep the same roll
// gains when tilted as we have when not tilted
const float avg_roll_factor = 0.5;
float tilt_scale = throttle_scaler * yaw_out * cos_tilt + avg_roll_factor * roll_out * sin_tilt;
if (fabsf(tilt_scale) > 1.0) {
tilt_scale = constrain_float(tilt_scale, -1.0, 1.0);
motors->limit.yaw = true;
}
const float tilt_offset = tilt_scale * yaw_range;
float left_tilt = base_output + tilt_offset;
float right_tilt = base_output - tilt_offset;
// if output saturation of both left and right then set yaw limit flag
if (((left_tilt > 1.0) || (left_tilt < 0.0)) &&
((right_tilt > 1.0) || (right_tilt < 0.0))) {
motors->limit.yaw = true;
}
// constrain and scale to ouput range
left_tilt = constrain_float(left_tilt,0.0,1.0) * 1000.0;
right_tilt = constrain_float(right_tilt,0.0,1.0) * 1000.0;
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, left_tilt);
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, right_tilt);
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRear, 1000.0 * constrain_float(base_output,0.0,1.0));
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearLeft, left_tilt);
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRearRight, right_tilt);
}
}
/*
control bicopter tiltrotors
*/
void Tiltrotor::bicopter_output(void)
{
if (type != TILT_TYPE_BICOPTER || quadplane.motor_test.running) {
// don't override motor test with motors_output
return;
}
if (!quadplane.in_vtol_mode() && fully_fwd()) {
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorLeft, -SERVO_MAX);
SRV_Channels::set_output_scaled(SRV_Channel::k_tiltMotorRight, -SERVO_MAX);
return;
}
float throttle = SRV_Channels::get_output_scaled(SRV_Channel::k_throttle);
if (quadplane.assisted_flight) {
quadplane.hold_stabilize(throttle * 0.01f);
quadplane.motors_output(true);
} else {
quadplane.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_yaw_angle * (1/90.0);
}
if (is_negative(tilt_right)) {
tilt_right *= tilt_yaw_angle * (1/90.0);
}
// reduce authority of bicopter as motors are tilted forwards
const float scaling = cosf(current_tilt * M_PI_2);
tilt_left *= scaling;
tilt_right *= scaling;
// add current tilt and constrain
tilt_left = constrain_float(-(current_tilt * SERVO_MAX) + tilt_left, -SERVO_MAX, SERVO_MAX);
tilt_right = constrain_float(-(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);
}
/*
when doing a forward transition of a tilt-vectored quadplane we use
euler angle control to maintain good yaw. This updates the yaw
target based on pilot input and target roll
*/
void Tiltrotor::update_yaw_target(void)
{
uint32_t now = AP_HAL::millis();
if (now - transition_yaw_set_ms > 100 ||
!is_zero(quadplane.get_pilot_input_yaw_rate_cds())) {
// lock initial yaw when transition is started or when
// pilot commands a yaw change. This allows us to track
// straight in transitions for tilt-vectored planes, but
// allows for turns when level transition is not wanted
transition_yaw_cd = quadplane.ahrs.yaw_sensor;
}
/*
now calculate the equivalent yaw rate for a coordinated turn for
the desired bank angle given the airspeed
*/
float aspeed;
bool have_airspeed = quadplane.ahrs.airspeed_estimate(aspeed);
if (have_airspeed && labs(plane.nav_roll_cd)>1000) {
float dt = (now - transition_yaw_set_ms) * 0.001;
// calculate the yaw rate to achieve the desired turn rate
const float airspeed_min = MAX(plane.aparm.airspeed_min,5);
const float yaw_rate_cds = fixedwing_turn_rate(plane.nav_roll_cd*0.01, MAX(aspeed,airspeed_min))*100;
transition_yaw_cd += yaw_rate_cds * dt;
}
transition_yaw_set_ms = now;
}
bool Tiltrotor_Transition::update_yaw_target(float& yaw_target_cd)
{
if (!(tiltrotor.is_vectored() &&
transition_state <= TRANSITION_TIMER)) {
return false;
}
tiltrotor.update_yaw_target();
yaw_target_cd = tiltrotor.transition_yaw_cd;
return true;
}
// return true if we should show VTOL view
bool Tiltrotor_Transition::show_vtol_view() const
{
bool show_vtol = quadplane.in_vtol_mode();
if (!show_vtol && tiltrotor.is_vectored() && transition_state <= TRANSITION_TIMER) {
// we use multirotor controls during fwd transition for
// vectored yaw vehicles
return true;
}
return show_vtol;
}
// return true if we are tilted over the max angle threshold
bool Tiltrotor::tilt_over_max_angle(void) const
{
const float tilt_threshold = (max_angle_deg/90.0f);
return (current_tilt > MIN(tilt_threshold, get_forward_flight_tilt()));
}
#endif // HAL_QUADPLANE_ENABLED