Files
PX4-Autopilot/src/modules/vtol_att_control/tailsitter.cpp
T
Silvan Fuhrer b16f16598b VTOL: remove virtual actuator_controls and instead use virtual torque/thrust topics
MC/FW rate controller and auto tuner: remove actuator_controls

AirshipAttControl: remove actuator_controls

MulticopterLandDetector: remove actuator_controls

mavlink streams vfr_hud and high_latency2: remove actuator_controls

RoverPositionController: remove actuator_controls

UUVAttitudeController: remove actuator_controls

battery: use length of thrust_setpoint for throttle compensation

VehicleMagnetometer: use length of thrust_setpoint for throttle compensation

Signed-off-by: Silvan Fuhrer
2023-03-16 11:55:45 +01:00

338 lines
11 KiB
C++

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/**
* @file tailsitter.cpp
*
* @author Roman Bapst <bapstroman@gmail.com>
* @author David Vorsin <davidvorsin@gmail.com>
*
*/
#include "tailsitter.h"
#include "vtol_att_control_main.h"
#define PITCH_TRANSITION_FRONT_P1 -1.1f // pitch angle to switch to TRANSITION_P2
#define PITCH_TRANSITION_BACK -0.25f // pitch angle to switch to MC
using namespace matrix;
Tailsitter::Tailsitter(VtolAttitudeControl *attc) :
VtolType(attc)
{
}
void
Tailsitter::parameters_update()
{
VtolType::updateParams();
}
void Tailsitter::update_vtol_state()
{
/* simple logic using a two way switch to perform transitions.
* after flipping the switch the vehicle will start tilting in MC control mode, picking up
* forward speed. After the vehicle has picked up enough and sufficient pitch angle the uav will go into FW mode.
* For the backtransition the pitch is controlled in MC mode again and switches to full MC control reaching the sufficient pitch angle.
*/
if (_vtol_vehicle_status->fixed_wing_system_failure) {
// Failsafe event, switch to MC mode immediately
_vtol_mode = vtol_mode::MC_MODE;
} else if (!_attc->is_fixed_wing_requested()) {
switch (_vtol_mode) { // user switchig to MC mode
case vtol_mode::MC_MODE:
break;
case vtol_mode::FW_MODE:
resetTransitionStates();
_vtol_mode = vtol_mode::TRANSITION_BACK;
break;
case vtol_mode::TRANSITION_FRONT_P1:
// failsafe into multicopter mode
_vtol_mode = vtol_mode::MC_MODE;
break;
case vtol_mode::TRANSITION_BACK:
const float pitch = Eulerf(Quatf(_v_att->q)).theta();
// check if we have reached pitch angle to switch to MC mode
if (pitch >= PITCH_TRANSITION_BACK || _time_since_trans_start > _param_vt_b_trans_dur.get()) {
_vtol_mode = vtol_mode::MC_MODE;
}
break;
}
} else { // user switchig to FW mode
switch (_vtol_mode) {
case vtol_mode::MC_MODE:
// initialise a front transition
_vtol_mode = vtol_mode::TRANSITION_FRONT_P1;
resetTransitionStates();
break;
case vtol_mode::FW_MODE:
break;
case vtol_mode::TRANSITION_FRONT_P1: {
if (isFrontTransitionCompleted()) {
_vtol_mode = vtol_mode::FW_MODE;
}
break;
}
case vtol_mode::TRANSITION_BACK:
// failsafe into fixed wing mode
_vtol_mode = vtol_mode::FW_MODE;
break;
}
}
// map tailsitter specific control phases to simple control modes
switch (_vtol_mode) {
case vtol_mode::MC_MODE:
_common_vtol_mode = mode::ROTARY_WING;
_flag_was_in_trans_mode = false;
break;
case vtol_mode::FW_MODE:
_common_vtol_mode = mode::FIXED_WING;
_flag_was_in_trans_mode = false;
break;
case vtol_mode::TRANSITION_FRONT_P1:
_common_vtol_mode = mode::TRANSITION_TO_FW;
break;
case vtol_mode::TRANSITION_BACK:
_common_vtol_mode = mode::TRANSITION_TO_MC;
break;
}
}
void Tailsitter::update_transition_state()
{
VtolType::update_transition_state();
const hrt_abstime now = hrt_absolute_time();
// we need the incoming (virtual) mc attitude setpoints to be recent, otherwise return (means the previous setpoint stays active)
if (_mc_virtual_att_sp->timestamp < (now - 1_s)) {
return;
}
if (!_flag_was_in_trans_mode) {
_flag_was_in_trans_mode = true;
if (_vtol_mode == vtol_mode::TRANSITION_BACK) {
// calculate rotation axis for transition.
_q_trans_start = Quatf(_v_att->q);
Vector3f z = -_q_trans_start.dcm_z();
_trans_rot_axis = z.cross(Vector3f(0, 0, -1));
// as heading setpoint we choose the heading given by the direction the vehicle points
float yaw_sp = atan2f(z(1), z(0));
// the intial attitude setpoint for a backtransition is a combination of the current fw pitch setpoint,
// the yaw setpoint and zero roll since we want wings level transition.
// If for some reason the fw attitude setpoint is not recent then don't sue it and assume 0 pitch
if (_fw_virtual_att_sp->timestamp > (now - 1_s)) {
_q_trans_start = Eulerf(0.0f, _fw_virtual_att_sp->pitch_body, yaw_sp);
} else {
_q_trans_start = Eulerf(0.0f, 0.f, yaw_sp);
}
// attitude during transitions are controlled by mc attitude control so rotate the desired attitude to the
// multirotor frame
_q_trans_start = _q_trans_start * Quatf(Eulerf(0, -M_PI_2_F, 0));
} else if (_vtol_mode == vtol_mode::TRANSITION_FRONT_P1) {
// initial attitude setpoint for the transition should be with wings level
_q_trans_start = Eulerf(0.0f, _mc_virtual_att_sp->pitch_body, _mc_virtual_att_sp->yaw_body);
Vector3f x = Dcmf(Quatf(_v_att->q)) * Vector3f(1, 0, 0);
_trans_rot_axis = -x.cross(Vector3f(0, 0, -1));
}
_q_trans_sp = _q_trans_start;
}
// ensure input quaternions are exactly normalized because acosf(1.00001) == NaN
_q_trans_sp.normalize();
// tilt angle (zero if vehicle nose points up (hover))
float cos_tilt = _q_trans_sp(0) * _q_trans_sp(0) - _q_trans_sp(1) * _q_trans_sp(1) - _q_trans_sp(2) *
_q_trans_sp(2) + _q_trans_sp(3) * _q_trans_sp(3);
cos_tilt = cos_tilt > 1.0f ? 1.0f : cos_tilt;
cos_tilt = cos_tilt < -1.0f ? -1.0f : cos_tilt;
const float tilt = acosf(cos_tilt);
if (_vtol_mode == vtol_mode::TRANSITION_FRONT_P1) {
// calculate pitching rate - and constrain to at least 0.1s transition time
const float trans_pitch_rate = M_PI_2_F / math::max(_param_vt_f_trans_dur.get(), 0.1f);
if (tilt < M_PI_2_F - math::radians(_param_fw_psp_off.get())) {
_q_trans_sp = Quatf(AxisAnglef(_trans_rot_axis,
_time_since_trans_start * trans_pitch_rate)) * _q_trans_start;
}
} else if (_vtol_mode == vtol_mode::TRANSITION_BACK) {
// calculate pitching rate - and constrain to at least 0.1s transition time
const float trans_pitch_rate = M_PI_2_F / math::max(_param_vt_b_trans_dur.get(), 0.1f);
if (tilt > 0.01f) {
_q_trans_sp = Quatf(AxisAnglef(_trans_rot_axis,
_time_since_trans_start * trans_pitch_rate)) * _q_trans_start;
}
}
_v_att_sp->thrust_body[2] = _mc_virtual_att_sp->thrust_body[2];
_v_att_sp->timestamp = hrt_absolute_time();
const Eulerf euler_sp(_q_trans_sp);
_v_att_sp->roll_body = euler_sp.phi();
_v_att_sp->pitch_body = euler_sp.theta();
_v_att_sp->yaw_body = euler_sp.psi();
_q_trans_sp.copyTo(_v_att_sp->q_d);
}
void Tailsitter::waiting_on_tecs()
{
// copy the last trust value from the front transition
_v_att_sp->thrust_body[0] = _thrust_transition;
}
void Tailsitter::update_fw_state()
{
VtolType::update_fw_state();
}
/**
* Write data to actuator output topic.
*/
void Tailsitter::fill_actuator_outputs()
{
_torque_setpoint_0->timestamp = hrt_absolute_time();
_torque_setpoint_0->timestamp_sample = _vehicle_torque_setpoint_virtual_mc->timestamp_sample;
_torque_setpoint_0->xyz[0] = 0.f;
_torque_setpoint_0->xyz[1] = 0.f;
_torque_setpoint_0->xyz[2] = 0.f;
_torque_setpoint_1->timestamp = hrt_absolute_time();
_torque_setpoint_1->timestamp_sample = _vehicle_torque_setpoint_virtual_fw->timestamp_sample;
_torque_setpoint_1->xyz[0] = 0.f;
_torque_setpoint_1->xyz[1] = 0.f;
_torque_setpoint_1->xyz[2] = 0.f;
_thrust_setpoint_0->timestamp = hrt_absolute_time();
_thrust_setpoint_0->timestamp_sample = _vehicle_thrust_setpoint_virtual_mc->timestamp_sample;
_thrust_setpoint_0->xyz[0] = 0.f;
_thrust_setpoint_0->xyz[1] = 0.f;
_thrust_setpoint_0->xyz[2] = 0.f;
_thrust_setpoint_1->timestamp = hrt_absolute_time();
_thrust_setpoint_1->timestamp_sample = _vehicle_thrust_setpoint_virtual_fw->timestamp_sample;
_thrust_setpoint_1->xyz[0] = 0.f;
_thrust_setpoint_1->xyz[1] = 0.f;
_thrust_setpoint_1->xyz[2] = 0.f;
// Motors
if (_vtol_mode == vtol_mode::FW_MODE) {
_thrust_setpoint_0->xyz[2] = -_vehicle_thrust_setpoint_virtual_fw->xyz[0];
/* allow differential thrust if enabled */
if (_param_vt_fw_difthr_en.get() & static_cast<int32_t>(VtFwDifthrEnBits::YAW_BIT)) {
_torque_setpoint_0->xyz[0] = _vehicle_torque_setpoint_virtual_fw->xyz[2] * _param_vt_fw_difthr_s_y.get();
}
if (_param_vt_fw_difthr_en.get() & static_cast<int32_t>(VtFwDifthrEnBits::PITCH_BIT)) {
_torque_setpoint_0->xyz[1] = _vehicle_torque_setpoint_virtual_fw->xyz[1] * _param_vt_fw_difthr_s_p.get();
}
if (_param_vt_fw_difthr_en.get() & static_cast<int32_t>(VtFwDifthrEnBits::ROLL_BIT)) {
_torque_setpoint_0->xyz[2] = -_vehicle_torque_setpoint_virtual_fw->xyz[0] * _param_vt_fw_difthr_s_r.get();
}
} else {
_torque_setpoint_0->xyz[0] = _vehicle_torque_setpoint_virtual_mc->xyz[0];
_torque_setpoint_0->xyz[1] = _vehicle_torque_setpoint_virtual_mc->xyz[1];
_torque_setpoint_0->xyz[2] = _vehicle_torque_setpoint_virtual_mc->xyz[2];
_thrust_setpoint_0->xyz[2] = _vehicle_thrust_setpoint_virtual_mc->xyz[2];
}
// Control surfaces
if (!_param_vt_elev_mc_lock.get() || _vtol_mode != vtol_mode::MC_MODE) {
_torque_setpoint_1->xyz[0] = _vehicle_torque_setpoint_virtual_fw->xyz[0];
_torque_setpoint_1->xyz[1] = _vehicle_torque_setpoint_virtual_fw->xyz[1];
_torque_setpoint_1->xyz[2] = _vehicle_torque_setpoint_virtual_fw->xyz[2];
}
}
bool Tailsitter::isFrontTransitionCompletedBase()
{
const bool airspeed_triggers_transition = PX4_ISFINITE(_airspeed_validated->calibrated_airspeed_m_s)
&& !_param_fw_arsp_mode.get() ;
bool transition_to_fw = false;
const float pitch = Eulerf(Quatf(_v_att->q)).theta();
if (pitch <= PITCH_TRANSITION_FRONT_P1) {
if (airspeed_triggers_transition) {
transition_to_fw = _airspeed_validated->calibrated_airspeed_m_s >= _param_vt_arsp_trans.get() ;
} else {
transition_to_fw = true;
}
}
return transition_to_fw;
}