void guidance_flip_enter(void)
{
flip_counter = 0;
flip_state = 0;
flip_rollout = false;
heading_save = stabilization_attitude_get_heading_i();
autopilot_mode_old = autopilot_mode;
}
void stabilization_attitude_set_failsafe_setpoint(void) {
/* set failsafe to zero roll/pitch and current heading */
int32_t heading2 = stabilization_attitude_get_heading_i() / 2;
PPRZ_ITRIG_COS(stab_att_sp_quat.qi, heading2);
stab_att_sp_quat.qx = 0;
stab_att_sp_quat.qy = 0;
PPRZ_ITRIG_SIN(stab_att_sp_quat.qz, heading2);
}
void stabilization_attitude_enter(void) {
/* reset psi setpoint to current psi angle */
stab_att_sp_euler.psi = stabilization_attitude_get_heading_i();
stabilization_attitude_ref_enter();
INT32_QUAT_ZERO(stabilization_att_sum_err_quat);
INT_EULERS_ZERO(stabilization_att_sum_err);
}
void stabilization_attitude_enter(void)
{
/* reset psi setpoint to current psi angle */
stab_att_sp_euler.psi = stabilization_attitude_get_heading_i();
attitude_ref_quat_int_enter(&att_ref_quat_i, stab_att_sp_euler.psi);
int32_quat_identity(&stabilization_att_sum_err_quat);
}
void stabilization_indi_enter(void)
{
/* reset psi setpoint to current psi angle */
stab_att_sp_euler.psi = stabilization_attitude_get_heading_i();
FLOAT_RATES_ZERO(indi.angular_accel_ref);
FLOAT_RATES_ZERO(indi.u_act_dyn);
FLOAT_RATES_ZERO(indi.u_in);
// Re-initialize filters
indi_init_filters();
}
void stabilization_indi_enter(void)
{
/* reset psi setpoint to current psi angle */
stab_att_sp_euler.psi = stabilization_attitude_get_heading_i();
FLOAT_RATES_ZERO(indi.rate.x);
FLOAT_RATES_ZERO(indi.rate.dx);
FLOAT_RATES_ZERO(indi.rate.ddx);
FLOAT_RATES_ZERO(indi.angular_accel_ref);
FLOAT_RATES_ZERO(indi.du);
FLOAT_RATES_ZERO(indi.u_act_dyn);
FLOAT_RATES_ZERO(indi.u_in);
FLOAT_RATES_ZERO(indi.u.x);
FLOAT_RATES_ZERO(indi.u.dx);
FLOAT_RATES_ZERO(indi.u.ddx);
}
void stabilization_attitude_enter(void)
{
/* reset psi setpoint to current psi angle */
stab_att_sp_euler.psi = stabilization_attitude_get_heading_i();
FLOAT_RATES_ZERO(indi.filtered_rate);
FLOAT_RATES_ZERO(indi.filtered_rate_deriv);
FLOAT_RATES_ZERO(indi.filtered_rate_2deriv);
FLOAT_RATES_ZERO(indi.angular_accel_ref);
FLOAT_RATES_ZERO(indi.u);
FLOAT_RATES_ZERO(indi.du);
FLOAT_RATES_ZERO(indi.u_act_dyn);
FLOAT_RATES_ZERO(indi.u_in);
FLOAT_RATES_ZERO(indi.udot);
FLOAT_RATES_ZERO(indi.udotdot);
}
/** Read attitude setpoint from RC as euler angles
* @param[in] coordinated_turn true if in horizontal mode forward
* @param[in] in_carefree true if in carefree mode
* @param[in] in_flight true if in flight
* @param[out] sp attitude setpoint as euler angles
*/
void stabilization_attitude_read_rc_setpoint_eulers(struct Int32Eulers *sp, bool_t in_flight, bool_t in_carefree, bool_t coordinated_turn) {
const int32_t max_rc_phi = (int32_t) ANGLE_BFP_OF_REAL(STABILIZATION_ATTITUDE_SP_MAX_PHI);
const int32_t max_rc_theta = (int32_t) ANGLE_BFP_OF_REAL(STABILIZATION_ATTITUDE_SP_MAX_THETA);
const int32_t max_rc_r = (int32_t) ANGLE_BFP_OF_REAL(STABILIZATION_ATTITUDE_SP_MAX_R);
sp->phi = (int32_t) ((radio_control.values[RADIO_ROLL] * max_rc_phi) / MAX_PPRZ);
sp->theta = (int32_t) ((radio_control.values[RADIO_PITCH] * max_rc_theta) / MAX_PPRZ);
if (in_flight) {
/* do not advance yaw setpoint if within a small deadband around stick center or if throttle is zero */
if (YAW_DEADBAND_EXCEEDED() && !THROTTLE_STICK_DOWN()) {
sp->psi += (int32_t) ((radio_control.values[RADIO_YAW] * max_rc_r) / MAX_PPRZ / RC_UPDATE_FREQ);
INT32_ANGLE_NORMALIZE(sp->psi);
}
if (coordinated_turn) {
//Coordinated turn
//feedforward estimate angular rotation omega = g*tan(phi)/v
//Take v = 9.81/1.3 m/s
int32_t omega;
const int32_t max_phi = ANGLE_BFP_OF_REAL(RadOfDeg(85.0));
if(abs(sp->phi) < max_phi)
omega = ANGLE_BFP_OF_REAL(1.3*tanf(ANGLE_FLOAT_OF_BFP(sp->phi)));
else //max 60 degrees roll, then take constant omega
omega = ANGLE_BFP_OF_REAL(1.3*1.72305* ((sp->phi > 0) - (sp->phi < 0)));
sp->psi += omega/RC_UPDATE_FREQ;
}
#ifdef STABILIZATION_ATTITUDE_SP_PSI_DELTA_LIMIT
// Make sure the yaw setpoint does not differ too much from the real yaw
// to prevent a sudden switch at 180 deg
const int32_t delta_limit = ANGLE_BFP_OF_REAL(STABILIZATION_ATTITUDE_SP_PSI_DELTA_LIMIT);
int32_t heading = stabilization_attitude_get_heading_i();
int32_t delta_psi = sp->psi - heading;
INT32_ANGLE_NORMALIZE(delta_psi);
if (delta_psi > delta_limit){
sp->psi = heading + delta_limit;
}
else if (delta_psi < -delta_limit){
sp->psi = heading - delta_limit;
}
INT32_ANGLE_NORMALIZE(sp->psi);
#endif
//Care Free mode
if (in_carefree) {
//care_free_heading has been set to current psi when entering care free mode.
int32_t cos_psi;
int32_t sin_psi;
int32_t temp_theta;
int32_t care_free_delta_psi_i;
care_free_delta_psi_i = sp->psi - ANGLE_BFP_OF_REAL(care_free_heading);
INT32_ANGLE_NORMALIZE(care_free_delta_psi_i);
PPRZ_ITRIG_SIN(sin_psi, care_free_delta_psi_i);
PPRZ_ITRIG_COS(cos_psi, care_free_delta_psi_i);
temp_theta = INT_MULT_RSHIFT(cos_psi, sp->theta, INT32_ANGLE_FRAC) - INT_MULT_RSHIFT(sin_psi, sp->phi, INT32_ANGLE_FRAC);
sp->phi = INT_MULT_RSHIFT(cos_psi, sp->phi, INT32_ANGLE_FRAC) - INT_MULT_RSHIFT(sin_psi, sp->theta, INT32_ANGLE_FRAC);
sp->theta = temp_theta;
}
}
else { /* if not flying, use current yaw as setpoint */
sp->psi = stateGetNedToBodyEulers_i()->psi;
}
}
/** Read attitude setpoint from RC as euler angles
* @param[in] coordinated_turn true if in horizontal mode forward
* @param[in] in_carefree true if in carefree mode
* @param[in] in_flight true if in flight
* @param[out] sp attitude setpoint as euler angles
*/
void stabilization_attitude_read_rc_setpoint_eulers(struct Int32Eulers *sp, bool in_flight, bool in_carefree,
bool coordinated_turn)
{
/* last time this function was called, used to calculate yaw setpoint update */
static float last_ts = 0.f;
sp->phi = get_rc_roll();
sp->theta = get_rc_pitch();
if (in_flight) {
/* calculate dt for yaw integration */
float dt = get_sys_time_float() - last_ts;
/* make sure nothing drastically weird happens, bound dt to 0.5sec */
Bound(dt, 0, 0.5);
/* do not advance yaw setpoint if within a small deadband around stick center or if throttle is zero */
if (YAW_DEADBAND_EXCEEDED() && !THROTTLE_STICK_DOWN()) {
sp->psi += get_rc_yaw() * dt;
INT32_ANGLE_NORMALIZE(sp->psi);
}
if (coordinated_turn) {
//Coordinated turn
//feedforward estimate angular rotation omega = g*tan(phi)/v
int32_t omega;
const int32_t max_phi = ANGLE_BFP_OF_REAL(RadOfDeg(60.0));
if (abs(sp->phi) < max_phi) {
omega = ANGLE_BFP_OF_REAL(9.81 / COORDINATED_TURN_AIRSPEED * tanf(ANGLE_FLOAT_OF_BFP(sp->phi)));
} else { //max 60 degrees roll
omega = ANGLE_BFP_OF_REAL(9.81 / COORDINATED_TURN_AIRSPEED * 1.72305 * ((sp->phi > 0) - (sp->phi < 0)));
}
sp->psi += omega * dt;
}
#ifdef STABILIZATION_ATTITUDE_SP_PSI_DELTA_LIMIT
// Make sure the yaw setpoint does not differ too much from the real yaw
// to prevent a sudden switch at 180 deg
const int32_t delta_limit = ANGLE_BFP_OF_REAL(STABILIZATION_ATTITUDE_SP_PSI_DELTA_LIMIT);
int32_t heading = stabilization_attitude_get_heading_i();
int32_t delta_psi = sp->psi - heading;
INT32_ANGLE_NORMALIZE(delta_psi);
if (delta_psi > delta_limit) {
sp->psi = heading + delta_limit;
} else if (delta_psi < -delta_limit) {
sp->psi = heading - delta_limit;
}
INT32_ANGLE_NORMALIZE(sp->psi);
#endif
//Care Free mode
if (in_carefree) {
//care_free_heading has been set to current psi when entering care free mode.
int32_t cos_psi;
int32_t sin_psi;
int32_t temp_theta;
int32_t care_free_delta_psi_i;
care_free_delta_psi_i = sp->psi - ANGLE_BFP_OF_REAL(care_free_heading);
INT32_ANGLE_NORMALIZE(care_free_delta_psi_i);
PPRZ_ITRIG_SIN(sin_psi, care_free_delta_psi_i);
PPRZ_ITRIG_COS(cos_psi, care_free_delta_psi_i);
temp_theta = INT_MULT_RSHIFT(cos_psi, sp->theta, INT32_ANGLE_FRAC) - INT_MULT_RSHIFT(sin_psi, sp->phi,
INT32_ANGLE_FRAC);
sp->phi = INT_MULT_RSHIFT(cos_psi, sp->phi, INT32_ANGLE_FRAC) - INT_MULT_RSHIFT(sin_psi, sp->theta, INT32_ANGLE_FRAC);
sp->theta = temp_theta;
}
} else { /* if not flying, use current yaw as setpoint */
sp->psi = stateGetNedToBodyEulers_i()->psi;
}
/* update timestamp for dt calculation */
last_ts = get_sys_time_float();
}
