v5.16/traffic__info_8c_source.html

 /*

  * Copyright (C) Pascal Brisset, Antoine Drouin (2008), Kirk Scheper (2016)

  *

  * This file is part of paparazzi

  *

  * paparazzi is free software; you can redistribute it and/or modify

  * it under the terms of the GNU General Public License as published by

  * the Free Software Foundation; either version 2, or (at your option)

  * any later version.

  *

  * paparazzi is distributed in the hope that it will be useful,

  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

  * GNU General Public License for more details.

  *

  * You should have received a copy of the GNU General Public License

  * along with paparazzi; see the file COPYING.  If not, see

  * <http://www.gnu.org/licenses/>.

  */

 #include "modules/multi/traffic_info.h"


 #include "generated/airframe.h"     // AC_ID

 #include "generated/flight_plan.h"  // NAV_MSL0


 #include "subsystems/datalink/datalink.h"

 #include "pprzlink/dl_protocol.h"   // datalink messages

 #include "pprzlink/messages.h"      // telemetry messages


 #include "state.h"

 #include "math/pprz_geodetic_utm.h"

 #include "math/pprz_geodetic_wgs84.h"


 /* number of ac being tracked */

 uint8_t ti_acs_idx;

 /* index of ac in the list of traffic info aircraft (ti_acs) */

 uint8_t ti_acs_id[NB_ACS_ID];

 /* container for available traffic info */

 struct acInfo ti_acs[NB_ACS];


 /* Geoid height (msl) over ellipsoid [mm] */

 int32_t geoid_height;


 void traffic_info_init(void)

 {

   memset(ti_acs_id, 0, NB_ACS_ID);


   ti_acs_id[0] = 0;  // ground station

   ti_acs_id[AC_ID] = 1;

   ti_acs[ti_acs_id[AC_ID]].ac_id = AC_ID;

   ti_acs_idx = 2;


   geoid_height = NAV_MSL0;

 }


 static void update_geoid_height(void) {

   if(bit_is_set(gps.valid_fields, GPS_VALID_HMSL_BIT) && bit_is_set(gps.valid_fields, GPS_VALID_POS_LLA_BIT))

   {

     geoid_height = gps.lla_pos.alt - gps.hmsl;

   } else if(bit_is_set(gps.valid_fields, GPS_VALID_POS_LLA_BIT))

   {

     geoid_height = wgs84_ellipsoid_to_geoid_i(gps.lla_pos.lat, gps.lla_pos.lon);

   } /* default is just keep last available height */

 }


 bool parse_acinfo_dl(uint8_t *buf)

 {

   uint8_t sender_id = SenderIdOfPprzMsg(buf);

   uint8_t msg_id = IdOfPprzMsg(buf);


   /* handle telemetry message */

 #if PPRZLINK_DEFAULT_VER == 2

   if (pprzlink_get_msg_class_id(buf) == DL_telemetry_CLASS_ID) {

 #else

   if (sender_id > 0) {

 #endif

     switch (msg_id) {

       case DL_GPS_SMALL: {

         uint32_t multiplex_speed = DL_GPS_SMALL_multiplex_speed(buf);


         // decode compressed values

         int16_t course = (int16_t)((multiplex_speed >> 21) & 0x7FF); // bits 31-21 course in decideg

         if (course & 0x400) {

           course |= 0xF800;  // fix for twos complements

         }

         course *= 2; // scale course by resolution

         int16_t gspeed = (int16_t)((multiplex_speed >> 10) & 0x7FF); // bits 20-10 ground speed cm/s

         if (gspeed & 0x400) {

           gspeed |= 0xF800;  // fix for twos complements

         }

         int16_t climb = (int16_t)(multiplex_speed & 0x3FF); // bits 9-0 z climb speed in cm/s

         if (climb & 0x200) {

           climb |= 0xFC00;  // fix for twos complements

         }


         set_ac_info_lla(sender_id,

                         DL_GPS_SMALL_lat(buf),

                         DL_GPS_SMALL_lon(buf),

                         (int32_t)DL_GPS_SMALL_alt(buf) * 10,

                         course,

                         gspeed,

                         climb,

                         gps_tow_from_sys_ticks(sys_time.nb_tick));

       }

       break;

       case DL_GPS: {

         set_ac_info_utm(sender_id,

                     DL_GPS_utm_east(buf),

                     DL_GPS_utm_north(buf),

                     DL_GPS_alt(buf),

                     DL_GPS_utm_zone(buf),

                     DL_GPS_course(buf),

                     DL_GPS_speed(buf),

                     DL_GPS_climb(buf),

                     DL_GPS_itow(buf));

       }

       break;

       case DL_GPS_LLA: {

         set_ac_info_lla(sender_id,

                         DL_GPS_LLA_lat(buf),

                         DL_GPS_LLA_lon(buf),

                         DL_GPS_LLA_alt(buf),

                         DL_GPS_LLA_course(buf),

                         DL_GPS_LLA_speed(buf),

                         DL_GPS_LLA_climb(buf),

                         DL_GPS_LLA_itow(buf));

       }

       break;

       default:

         return FALSE;

     }

   /* handle datalink message */

   } else {

     switch (msg_id) {

       case DL_ACINFO: {

         set_ac_info_utm(DL_ACINFO_ac_id(buf),

                         DL_ACINFO_utm_east(buf),

                         DL_ACINFO_utm_north(buf),

                         DL_ACINFO_alt(buf) * 10,

                         DL_ACINFO_utm_zone(buf),

                         DL_ACINFO_course(buf),

                         DL_ACINFO_speed(buf),

                         DL_ACINFO_climb(buf),

                         DL_ACINFO_itow(buf));

       }

       break;

       case DL_ACINFO_LLA: {

         set_ac_info_lla(DL_ACINFO_LLA_ac_id(buf),

                   DL_ACINFO_LLA_lat(buf),

                   DL_ACINFO_LLA_lon(buf),

                   DL_ACINFO_LLA_alt(buf) * 10,

                   DL_ACINFO_LLA_course(buf),

                   DL_ACINFO_LLA_speed(buf),

                   DL_ACINFO_LLA_climb(buf),

                   DL_ACINFO_LLA_itow(buf));

       }

       break;

       default:

         return FALSE;

     }

   }

   return TRUE;

 }


 void set_ac_info_utm(uint8_t id, uint32_t utm_east, uint32_t utm_north, uint32_t alt, uint8_t utm_zone, uint16_t course,

                  uint16_t gspeed, uint16_t climb, uint32_t itow)

 {

   if (ti_acs_idx < NB_ACS) {

     if (id > 0 && ti_acs_id[id] == 0) {    // new aircraft id

       ti_acs_id[id] = ti_acs_idx++;

       ti_acs[ti_acs_id[id]].ac_id = id;

     }


     ti_acs[ti_acs_id[id]].status = 0;


     uint16_t my_zone = state.utm_origin_f.zone;

     if (utm_zone == my_zone) {

       ti_acs[ti_acs_id[id]].utm_pos_i.east = utm_east;

       ti_acs[ti_acs_id[id]].utm_pos_i.north = utm_north;

       ti_acs[ti_acs_id[id]].utm_pos_i.alt = alt;

       ti_acs[ti_acs_id[id]].utm_pos_i.zone = utm_zone;

       SetBit(ti_acs[ti_acs_id[id]].status, AC_INFO_POS_UTM_I);


     } else { // store other uav in utm extended zone

       struct UtmCoor_i utm = {.east = utm_east, .north = utm_north, .alt = alt, .zone = utm_zone};

       struct LlaCoor_i lla;

       lla_of_utm_i(&lla, &utm);

       LLA_COPY(ti_acs[ti_acs_id[id]].lla_pos_i, lla);

       SetBit(ti_acs[ti_acs_id[id]].status, AC_INFO_POS_LLA_I);


       utm.zone = my_zone;

       utm_of_lla_i(&utm, &lla);


       UTM_COPY(ti_acs[ti_acs_id[id]].utm_pos_i, utm);

       SetBit(ti_acs[ti_acs_id[id]].status, AC_INFO_POS_UTM_I);

     }


     ti_acs[ti_acs_id[id]].course = RadOfDeciDeg(course);

     ti_acs[ti_acs_id[id]].gspeed = MOfCm(gspeed);

     ti_acs[ti_acs_id[id]].climb = MOfCm(climb);

     SetBit(ti_acs[ti_acs_id[id]].status, AC_INFO_VEL_LOCAL_F);


     ti_acs[ti_acs_id[id]].itow = itow;

   }

 }


 void set_ac_info_lla(uint8_t id, int32_t lat, int32_t lon, int32_t alt,

                      int16_t course, uint16_t gspeed, int16_t climb, uint32_t itow)

 {

   if (ti_acs_idx < NB_ACS) {

     if (id > 0 && ti_acs_id[id] == 0) {

       ti_acs_id[id] = ti_acs_idx++;

       ti_acs[ti_acs_id[id]].ac_id = id;

     }


     ti_acs[ti_acs_id[id]].status = 0;


     struct LlaCoor_i lla = {.lat = lat, .lon = lon, .alt = alt};

     LLA_COPY(ti_acs[ti_acs_id[id]].lla_pos_i, lla);

     SetBit(ti_acs[ti_acs_id[id]].status, AC_INFO_POS_LLA_I);


     ti_acs[ti_acs_id[id]].course = RadOfDeciDeg(course);

     ti_acs[ti_acs_id[id]].gspeed = MOfCm(gspeed);

     ti_acs[ti_acs_id[id]].climb = MOfCm(climb);

     SetBit(ti_acs[ti_acs_id[id]].status, AC_INFO_VEL_LOCAL_F);


     ti_acs[ti_acs_id[id]].itow = itow;

   }

 }


 /* Conversion funcitons for computing ac position in requested reference frame from

  * any other available reference frame

  */


 /* compute UTM position of aircraft with ac_id (int) */

 void acInfoCalcPositionUtm_i(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I))

   {

     return;

   }


   /* LLA_i -> UTM_i is more accurate than from UTM_f */

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I))

   {

     // use my zone as reference, i.e zone extend

     ti_acs[ac_nr].utm_pos_i.zone = state.utm_origin_f.zone;

     utm_of_lla_i(&ti_acs[ac_nr].utm_pos_i, &ti_acs[ac_nr].lla_pos_i);

     update_geoid_height();

     ti_acs[ac_nr].utm_pos_i.alt -= geoid_height;

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F))

   {

     UTM_BFP_OF_REAL(ti_acs[ac_nr].utm_pos_i, ti_acs[ac_nr].utm_pos_f);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F))

   {

     // use my zone as reference, i.e zone extend

     ti_acs[ac_nr].utm_pos_i.zone = state.utm_origin_f.zone;

     utm_of_lla_f(&ti_acs[ac_nr].utm_pos_f, &ti_acs[ac_nr].lla_pos_f);

     update_geoid_height();

     ti_acs[ac_nr].utm_pos_f.alt -= geoid_height/1000.;

     SetBit(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F);

     UTM_BFP_OF_REAL(ti_acs[ac_nr].utm_pos_i, ti_acs[ac_nr].utm_pos_f);

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I);

 }


 /* compute LLA position of aircraft with ac_id (int) */

 void acInfoCalcPositionLla_i(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F))

   {

     LLA_BFP_OF_REAL(ti_acs[ac_nr].lla_pos_i, ti_acs[ac_nr].lla_pos_f);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I))

   {

     lla_of_utm_i(&ti_acs[ac_nr].lla_pos_i, &ti_acs[ac_nr].utm_pos_i);

     update_geoid_height();

     ti_acs[ac_nr].lla_pos_i.alt += geoid_height;

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F))

   {

     lla_of_utm_f(&ti_acs[ac_nr].lla_pos_f, &ti_acs[ac_nr].utm_pos_f);

     update_geoid_height();

     ti_acs[ac_nr].lla_pos_f.alt += geoid_height/1000.;

     SetBit(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F);

     LLA_BFP_OF_REAL(ti_acs[ac_nr].lla_pos_i, ti_acs[ac_nr].lla_pos_f);

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I);

 }


 /* compute ENU position of aircraft with ac_id (int) */

 void acInfoCalcPositionEnu_i(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_ENU_I))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_ENU_F))

   {

     ENU_BFP_OF_REAL(ti_acs[ac_nr].enu_pos_i, ti_acs[ac_nr].enu_pos_f);

   }

   else if (state.ned_initialized_i)

   {

     if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I) || bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I))

     {

       enu_of_lla_point_i(&ti_acs[ac_nr].enu_pos_i, &state.ned_origin_i, acInfoGetPositionLla_i(ac_id));

     } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F) || bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F))

     {

       enu_of_lla_point_f(&ti_acs[ac_nr].enu_pos_f, &state.ned_origin_f, acInfoGetPositionLla_f(ac_id));

       SetBit(ti_acs[ac_nr].status, AC_INFO_POS_ENU_F);

       ENU_BFP_OF_REAL(ti_acs[ac_nr].enu_pos_i, ti_acs[ac_nr].enu_pos_f)

     }

   } else if (state.utm_initialized_f)

   {

     /* if utm origin is initialized we use the ENU = UTM - UTM_ORIGIN as in state to facilitate comparison */

     ENU_OF_UTM_DIFF(ti_acs[ac_nr].enu_pos_f, *acInfoGetPositionUtm_f(ac_id), state.utm_origin_f);

     SetBit(ti_acs[ac_nr].status, AC_INFO_POS_ENU_F);

     ENU_BFP_OF_REAL(ti_acs[ac_nr].enu_pos_i, ti_acs[ac_nr].enu_pos_f);

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_POS_ENU_I);

 }


 /* compute UTM position of aircraft with ac_id (float) */

 void acInfoCalcPositionUtm_f(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I))

   {

     UTM_FLOAT_OF_BFP(ti_acs[ac_nr].utm_pos_f, ti_acs[ac_nr].utm_pos_i);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I))

   {

     // use my zone as reference, i.e zone extend

     ti_acs[ac_nr].utm_pos_i.zone = state.utm_origin_f.zone;

     utm_of_lla_i(&ti_acs[ac_nr].utm_pos_i, &ti_acs[ac_nr].lla_pos_i);

     update_geoid_height();

     ti_acs[ac_nr].utm_pos_i.alt -= geoid_height;

     SetBit(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I);

     UTM_FLOAT_OF_BFP(ti_acs[ac_nr].utm_pos_f, ti_acs[ac_nr].utm_pos_i);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F))

   {

     /* not very accurate with float ~5cm */

     ti_acs[ac_nr].utm_pos_f.zone = state.utm_origin_f.zone;

     utm_of_lla_f(&ti_acs[ac_nr].utm_pos_f, &ti_acs[ac_nr].lla_pos_f);

     update_geoid_height();

     ti_acs[ac_nr].utm_pos_f.alt -= geoid_height/1000.;

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F);

 }


 /* compute LLA position of aircraft with ac_id (float) */

 void acInfoCalcPositionLla_f(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I))

   {

     LLA_FLOAT_OF_BFP(ti_acs[ac_nr].lla_pos_f, ti_acs[ac_nr].lla_pos_i);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I))

   {

     lla_of_utm_i(&ti_acs[ac_nr].lla_pos_i, &ti_acs[ac_nr].utm_pos_i);

     update_geoid_height();

     ti_acs[ac_nr].lla_pos_i.alt += geoid_height;

     SetBit(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I);

     LLA_FLOAT_OF_BFP(ti_acs[ac_nr].lla_pos_f, ti_acs[ac_nr].lla_pos_i);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F))

   {

     lla_of_utm_f(&ti_acs[ac_nr].lla_pos_f, &ti_acs[ac_nr].utm_pos_f);

     update_geoid_height();

     ti_acs[ac_nr].lla_pos_f.alt += geoid_height/1000.;

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F);

 }


 /* compute ENU position of aircraft with ac_id (float) */

 void acInfoCalcPositionEnu_f(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_ENU_F))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_ENU_I))

   {

     ENU_FLOAT_OF_BFP(ti_acs[ac_nr].enu_pos_f, ti_acs[ac_nr].enu_pos_i);

   }

   else if (state.ned_initialized_i)

   {

     if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_F) || bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_F))

     {

       enu_of_lla_point_f(&ti_acs[ac_nr].enu_pos_f, &state.ned_origin_f, acInfoGetPositionLla_f(ac_id));

     } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_LLA_I) || bit_is_set(ti_acs[ac_nr].status, AC_INFO_POS_UTM_I))

     {

       enu_of_lla_point_i(&ti_acs[ac_nr].enu_pos_i, &state.ned_origin_i, acInfoGetPositionLla_i(ac_id));

       SetBit(ti_acs[ac_nr].status, AC_INFO_POS_ENU_I);

       ENU_FLOAT_OF_BFP(ti_acs[ac_nr].enu_pos_f, ti_acs[ac_nr].enu_pos_i);

     }

   } else if (state.utm_initialized_f)

   {

     /* if utm origin is initialized we use the ENU = UTM - UTM_ORIGIN as in state to facilitate comparison */

     ENU_OF_UTM_DIFF(ti_acs[ac_nr].enu_pos_f, *acInfoGetPositionUtm_f(ac_id), state.utm_origin_f);

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_POS_ENU_F);

 }


 /* compute ENU velocity of aircraft with ac_id (int) */

 void acInfoCalcVelocityEnu_i(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_I))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_F))

   {

     SPEEDS_BFP_OF_REAL(ti_acs[ac_nr].enu_vel_i, ti_acs[ac_nr].enu_vel_f);

   } else {

     ti_acs[ac_nr].enu_vel_f.x = ti_acs[ac_nr].gspeed * sinf(ti_acs[ac_nr].course);

     ti_acs[ac_nr].enu_vel_f.y = ti_acs[ac_nr].gspeed * cosf(ti_acs[ac_nr].course);

     ti_acs[ac_nr].enu_vel_f.z = ti_acs[ac_nr].climb;

     SetBit(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_F);

     SPEEDS_BFP_OF_REAL(ti_acs[ac_nr].enu_vel_i, ti_acs[ac_nr].enu_vel_f);

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_I);

 }


 /* compute ENU position of aircraft with ac_id (float) */

 void acInfoCalcVelocityEnu_f(uint8_t ac_id)

 {

   uint8_t ac_nr = ti_acs_id[ac_id];

   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_F))

   {

     return;

   }


   if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_I))

   {

     SPEEDS_FLOAT_OF_BFP(ti_acs[ac_nr].enu_vel_f, ti_acs[ac_nr].enu_vel_i);

   } else if (bit_is_set(ti_acs[ac_nr].status, AC_INFO_VEL_LOCAL_F)) {

     ti_acs[ac_nr].enu_vel_f.x = ti_acs[ac_nr].gspeed * sinf(ti_acs[ac_nr].course);

     ti_acs[ac_nr].enu_vel_f.y = ti_acs[ac_nr].gspeed * cosf(ti_acs[ac_nr].course);

     ti_acs[ac_nr].enu_vel_f.z = ti_acs[ac_nr].climb;

   }

   SetBit(ti_acs[ac_nr].status, AC_INFO_VEL_ENU_F);

 }

acInfoGetPositionUtm_f
static struct UtmCoor_f * acInfoGetPositionUtm_f(uint8_t ac_id)
Get position from UTM coordinates (float).
Definition: traffic_info.h:361

uint16_t
unsigned short uint16_t
Definition: types.h:16

ac_id
uint8_t ac_id
Definition: sim_ap.c:48

SPEEDS_BFP_OF_REAL
#define SPEEDS_BFP_OF_REAL(_ef, _ei)
Definition: pprz_algebra.h:789

UtmCoor_i::north
int32_t north
in centimeters
Definition: pprz_geodetic_int.h:87

State::utm_initialized_f
bool utm_initialized_f
True if utm origin (float) coordinate frame is initialsed.
Definition: state.h:236

acInfoCalcPositionUtm_f
void acInfoCalcPositionUtm_f(uint8_t ac_id)
Definition: traffic_info.c:342

acInfo::lla_pos_i
struct LlaCoor_i lla_pos_i
Position in Latitude, Longitude and Altitude.
Definition: traffic_info.h:78

geoid_height
int32_t geoid_height
Definition: traffic_info.c:48

acInfo::enu_vel_f
struct EnuCoor_f enu_vel_f
speed in North East Down coordinates
Definition: traffic_info.h:114

UtmCoor_f::alt
float alt
in meters (above WGS84 reference ellipsoid or above MSL)
Definition: pprz_geodetic_float.h:84

set_ac_info_lla
void set_ac_info_lla(uint8_t id, int32_t lat, int32_t lon, int32_t alt, int16_t course, uint16_t gspeed, int16_t climb, uint32_t itow)
Set Aircraft info.
Definition: traffic_info.c:218

acInfoCalcVelocityEnu_f
void acInfoCalcVelocityEnu_f(uint8_t ac_id)
Definition: traffic_info.c:456

acInfoCalcVelocityEnu_i
void acInfoCalcVelocityEnu_i(uint8_t ac_id)
Definition: traffic_info.c:434

GpsState::valid_fields
uint8_t valid_fields
bitfield indicating valid fields (GPS_VALID_x_BIT)
Definition: gps.h:88

State::ned_origin_f
struct LtpDef_f ned_origin_f
Definition of the local (flat earth) coordinate system.
Definition: state.h:220

parse_acinfo_dl
bool parse_acinfo_dl(uint8_t *buf)
Parse all datalink or telemetry messages that contain global position of other acs Messages currently...
Definition: traffic_info.c:76

datalink.h
Handling of messages coming from ground and other A/Cs.

acInfo::climb
float climb
m/s
Definition: traffic_info.h:118

acInfo::itow
uint32_t itow
ms
Definition: traffic_info.h:119

acInfoCalcPositionUtm_i
void acInfoCalcPositionUtm_i(uint8_t ac_id)
Definition: traffic_info.c:247

acInfoCalcPositionLla_i
void acInfoCalcPositionLla_i(uint8_t ac_id)
Definition: traffic_info.c:280

acInfo::utm_pos_f
struct UtmCoor_f utm_pos_f
Position in UTM coordinates.
Definition: traffic_info.h:97

AC_INFO_POS_LLA_I
#define AC_INFO_POS_LLA_I
Definition: traffic_info.h:48

acInfo::gspeed
float gspeed
m/s
Definition: traffic_info.h:117

AC_INFO_POS_UTM_F
#define AC_INFO_POS_UTM_F
Definition: traffic_info.h:50

UTM_FLOAT_OF_BFP
#define UTM_FLOAT_OF_BFP(_o, _i)
Definition: pprz_geodetic_int.h:247

AC_INFO_VEL_ENU_I
#define AC_INFO_VEL_ENU_I
Definition: traffic_info.h:53

UtmCoor_i::east
int32_t east
in centimeters
Definition: pprz_geodetic_int.h:88

enu_of_lla_point_f
void enu_of_lla_point_f(struct EnuCoor_f *enu, struct LtpDef_f *def, struct LlaCoor_f *lla)
Definition: pprz_geodetic_float.c:112

SPEEDS_FLOAT_OF_BFP
#define SPEEDS_FLOAT_OF_BFP(_ef, _ei)
Definition: pprz_algebra.h:783

LlaCoor_i
vector in Latitude, Longitude and Altitude
Definition: pprz_geodetic_int.h:59

sys_time::nb_tick
volatile uint32_t nb_tick
SYS_TIME_TICKS since startup.
Definition: sys_time.h:74

acInfo::status
uint16_t status
Holds the status bits for all acinfo position and velocity representations.
Definition: traffic_info.h:64

NB_ACS_ID
#define NB_ACS_ID
Definition: rssi.c:35

acInfo::ac_id
uint8_t ac_id
Definition: traffic_info.h:58

FALSE
#define FALSE
Definition: std.h:5

LlaCoor_i::alt
int32_t alt
in millimeters above WGS84 reference ellipsoid
Definition: pprz_geodetic_int.h:62

pprz_geodetic_wgs84.h
WGS-84 Geoid Heights.

set_ac_info_utm
void set_ac_info_utm(uint8_t id, uint32_t utm_east, uint32_t utm_north, uint32_t alt, uint8_t utm_zone, uint16_t course, uint16_t gspeed, uint16_t climb, uint32_t itow)
Set Aircraft info.
Definition: traffic_info.c:176

UtmCoor_i::zone
uint8_t zone
UTM zone number.
Definition: pprz_geodetic_int.h:90

UTM_BFP_OF_REAL
#define UTM_BFP_OF_REAL(_o, _i)
Definition: pprz_geodetic_int.h:261

TRUE
#define TRUE
Definition: std.h:4

GpsState::hmsl
int32_t hmsl
height above mean sea level (MSL) in mm
Definition: gps.h:94

acInfoCalcPositionEnu_i
void acInfoCalcPositionEnu_i(uint8_t ac_id)
Definition: traffic_info.c:308

EnuCoor_f::x
float x
in meters
Definition: pprz_geodetic_float.h:73

acInfo::utm_pos_i
struct UtmCoor_i utm_pos_i
Position in UTM coordinates.
Definition: traffic_info.h:71

NB_ACS
#define NB_ACS
Definition: rssi.c:38

update_geoid_height
static void update_geoid_height(void)
Update estimate of the geoid height Requires an available hsml and/or lla measurement, if not available value isn't updated.
Definition: traffic_info.c:66

lla_of_utm_i
void lla_of_utm_i(struct LlaCoor_i *lla, struct UtmCoor_i *utm)
Convert a UTM to LLA.
Definition: pprz_geodetic_int.c:452

status
uint8_t status
Definition: nps_radio_control_spektrum.c:101

lla_of_utm_f
void lla_of_utm_f(struct LlaCoor_f *lla, struct UtmCoor_f *utm)
Definition: pprz_geodetic_float.c:344

uint32_t
unsigned long uint32_t
Definition: types.h:18

int16_t
signed short int16_t
Definition: types.h:17

ENU_FLOAT_OF_BFP
#define ENU_FLOAT_OF_BFP(_o, _i)
Definition: pprz_geodetic_int.h:202

GPS_VALID_HMSL_BIT
#define GPS_VALID_HMSL_BIT
Definition: gps.h:53

LlaCoor_i::lon
int32_t lon
in degrees*1e7
Definition: pprz_geodetic_int.h:61

AC_INFO_POS_ENU_I
#define AC_INFO_POS_ENU_I
Definition: traffic_info.h:49

acInfoGetPositionLla_f
static struct LlaCoor_f * acInfoGetPositionLla_f(uint8_t ac_id)
Get position from LLA coordinates (float).
Definition: traffic_info.h:372

utm_of_lla_i
void utm_of_lla_i(struct UtmCoor_i *utm, struct LlaCoor_i *lla)
Convert a LLA to UTM.
Definition: pprz_geodetic_int.c:423

UtmCoor_f::zone
uint8_t zone
UTM zone number.
Definition: pprz_geodetic_float.h:85

State::utm_origin_f
struct UtmCoor_f utm_origin_f
Definition of the origin of Utm coordinate system.
Definition: state.h:233

LLA_COPY
#define LLA_COPY(_pos1, _pos2)
Definition: pprz_geodetic.h:58

int32_t
signed long int32_t
Definition: types.h:19

State::ned_initialized_i
bool ned_initialized_i
true if local int coordinate frame is initialsed
Definition: state.h:171

AC_INFO_POS_ENU_F
#define AC_INFO_POS_ENU_F
Definition: traffic_info.h:52

traffic_info_init
void traffic_info_init(void)
Definition: traffic_info.c:50

State::ned_origin_i
struct LtpDef_i ned_origin_i
Definition of the local (flat earth) coordinate system.
Definition: state.h:166

LlaCoor_f::alt
float alt
in meters (normally above WGS84 reference ellipsoid)
Definition: pprz_geodetic_float.h:57

pprz_geodetic_utm.h
Constants UTM (Mercator) projections.

acInfoCalcPositionEnu_f
void acInfoCalcPositionEnu_f(uint8_t ac_id)
Definition: traffic_info.c:402

UtmCoor_i::alt
int32_t alt
in millimeters (above WGS84 reference ellipsoid or above MSL)
Definition: pprz_geodetic_int.h:89

acInfo::lla_pos_f
struct LlaCoor_f lla_pos_f
Position in Latitude, Longitude and Altitude.
Definition: traffic_info.h:104

uint8_t
unsigned char uint8_t
Definition: types.h:14

state.h
API to get/set the generic vehicle states.

EnuCoor_f::z
float z
in meters
Definition: pprz_geodetic_float.h:75

AC_INFO_VEL_LOCAL_F
#define AC_INFO_VEL_LOCAL_F
Definition: traffic_info.h:55

course
static int16_t course[3]
Definition: airspeed_uADC.c:57

ti_acs
struct acInfo ti_acs[NB_ACS]
Definition: traffic_info.c:45

LLA_BFP_OF_REAL
#define LLA_BFP_OF_REAL(_o, _i)
Definition: pprz_geodetic_int.h:171

GPS_VALID_POS_LLA_BIT
#define GPS_VALID_POS_LLA_BIT
Definition: gps.h:49

gps_tow_from_sys_ticks
uint32_t gps_tow_from_sys_ticks(uint32_t sys_ticks)
Convert time in sys_time ticks to GPS time of week.
Definition: gps.c:355

ENU_BFP_OF_REAL
#define ENU_BFP_OF_REAL(_o, _i)
Definition: pprz_geodetic_int.h:194

GpsState::lla_pos
struct LlaCoor_i lla_pos
position in LLA (lat,lon: deg*1e7; alt: mm over ellipsoid)
Definition: gps.h:92

AC_INFO_POS_UTM_I
#define AC_INFO_POS_UTM_I
Definition: traffic_info.h:47

acInfo::course
float course
rad
Definition: traffic_info.h:116

enu_of_lla_point_i
void enu_of_lla_point_i(struct EnuCoor_i *enu, struct LtpDef_i *def, struct LlaCoor_i *lla)
Convert a point from LLA to local ENU.
Definition: pprz_geodetic_int.c:295

LlaCoor_i::lat
int32_t lat
in degrees*1e7
Definition: pprz_geodetic_int.h:60

acInfoCalcPositionLla_f
void acInfoCalcPositionLla_f(uint8_t ac_id)
Definition: traffic_info.c:374

acInfoGetPositionLla_i
static struct LlaCoor_i * acInfoGetPositionLla_i(uint8_t ac_id)
Get position from LLA coordinates (int).
Definition: traffic_info.h:339

ti_acs_idx
uint8_t ti_acs_idx
Definition: traffic_info.c:41

EnuCoor_f::y
float y
in meters
Definition: pprz_geodetic_float.h:74

ENU_OF_UTM_DIFF
#define ENU_OF_UTM_DIFF(_pos, _utm1, _utm2)
Definition: pprz_geodetic.h:78

gps
struct GpsState gps
global GPS state
Definition: gps.c:69

AC_INFO_POS_LLA_F
#define AC_INFO_POS_LLA_F
Definition: traffic_info.h:51

LLA_FLOAT_OF_BFP
#define LLA_FLOAT_OF_BFP(_o, _i)
Definition: pprz_geodetic_int.h:177

wgs84_ellipsoid_to_geoid_i
static int32_t wgs84_ellipsoid_to_geoid_i(int32_t lat, int32_t lon)
Get WGS84 ellipsoid/geoid separation.
Definition: pprz_geodetic_wgs84.h:81

state
struct State state
Definition: state.c:36

utm_of_lla_f
void utm_of_lla_f(struct UtmCoor_f *utm, struct LlaCoor_f *lla)
Definition: pprz_geodetic_float.c:308

AC_INFO_VEL_ENU_F
#define AC_INFO_VEL_ENU_F
Definition: traffic_info.h:54

traffic_info.h

UtmCoor_i
position in UTM coordinates
Definition: pprz_geodetic_int.h:86

ti_acs_id
uint8_t ti_acs_id[NB_ACS_ID]
Definition: traffic_info.c:43

acInfo
Definition: traffic_info.h:57

sys_time
Definition: sys_time.h:71

UTM_COPY
#define UTM_COPY(_u1, _u2)
Definition: pprz_geodetic.h:71