mirror of https://github.com/ArduPilot/ardupilot
472 lines
14 KiB
C++
472 lines
14 KiB
C++
/*
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SITL handling
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This simulates a GPS on a serial port
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Andrew Tridgell November 2011
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*/
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#include "SIM_GPS.h"
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#if HAL_SIM_GPS_ENABLED
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#include <time.h>
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#include <AP_BoardConfig/AP_BoardConfig.h>
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#include <AP_HAL/AP_HAL.h>
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#include <SITL/SITL.h>
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#include <AP_InternalError/AP_InternalError.h>
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#include "SIM_GPS_FILE.h"
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#include "SIM_GPS_Trimble.h"
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#include "SIM_GPS_MSP.h"
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#include "SIM_GPS_NMEA.h"
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#include "SIM_GPS_NOVA.h"
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#include "SIM_GPS_SBP2.h"
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#include "SIM_GPS_SBP.h"
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#include "SIM_GPS_UBLOX.h"
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// the number of GPS leap seconds - copied from AP_GPS.h
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#define GPS_LEAPSECONDS_MILLIS 18000ULL
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extern const AP_HAL::HAL& hal;
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using namespace SITL;
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// ensure the backend we have allocated matches the one that's configured:
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GPS_Backend::GPS_Backend(GPS &_front, uint8_t _instance)
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: front{_front},
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instance{_instance}
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{
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_sitl = AP::sitl();
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}
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ssize_t GPS_Backend::write_to_autopilot(const char *p, size_t size) const
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{
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return front.write_to_autopilot(p, size);
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}
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ssize_t GPS_Backend::read_from_autopilot(char *buffer, size_t size) const
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{
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return front.read_from_autopilot(buffer, size);
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}
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GPS::GPS(uint8_t _instance) :
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SerialDevice(8192, 2048),
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instance{_instance}
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{
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}
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uint32_t GPS::device_baud() const
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{
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if (backend == nullptr) {
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return 0;
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}
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return backend->device_baud();
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}
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/*
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write some bytes from the simulated GPS
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*/
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ssize_t GPS::write_to_autopilot(const char *p, size_t size) const
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{
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// the second GPS instance fails in a different way to the first;
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// the first will start sending back 3 satellites, the second just
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// stops responding when disabled. This is not necessarily a good
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// thing.
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if (instance == 1 && _sitl->gps_disable[instance]) {
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return -1;
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}
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const float byteloss = _sitl->gps_byteloss[instance];
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// shortcut if we're not doing byteloss:
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if (!is_positive(byteloss)) {
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return SerialDevice::write_to_autopilot(p, size);
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}
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size_t ret = 0;
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while (size--) {
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float r = ((((unsigned)random()) % 1000000)) / 1.0e4;
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if (r < byteloss) {
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// lose the byte
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p++;
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continue;
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}
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const ssize_t pret = SerialDevice::write_to_autopilot(p, 1);
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if (pret == 0) {
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// no space?
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return ret;
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}
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if (pret != 1) {
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// error has occured?
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return pret;
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}
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ret++;
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p++;
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}
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return ret;
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}
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/*
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get timeval using simulation time
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*/
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void GPS_Backend::simulation_timeval(struct timeval *tv)
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{
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uint64_t now = AP_HAL::micros64();
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static uint64_t first_usec;
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static struct timeval first_tv;
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if (first_usec == 0) {
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first_usec = now;
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first_tv.tv_sec = AP::sitl()->start_time_UTC;
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}
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*tv = first_tv;
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tv->tv_sec += now / 1000000ULL;
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uint64_t new_usec = tv->tv_usec + (now % 1000000ULL);
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tv->tv_sec += new_usec / 1000000ULL;
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tv->tv_usec = new_usec % 1000000ULL;
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}
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/*
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simple simulation of jamming
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*/
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void GPS::simulate_jamming(struct GPS_Data &d)
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{
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auto &jam = jamming[instance];
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const uint32_t now_ms = AP_HAL::millis();
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if (now_ms - jam.last_jam_ms > 1000) {
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jam.jam_start_ms = now_ms;
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jam.latitude = d.latitude;
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jam.longitude = d.longitude;
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}
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jam.last_jam_ms = now_ms;
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// how often each of the key state variables change during jamming
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const float vz_change_hz = 0.5;
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const float vel_change_hz = 0.8;
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const float pos_change_hz = 1.1;
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const float sats_change_hz = 3;
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const float acc_change_hz = 3;
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if (now_ms - jam.jam_start_ms < unsigned(1000U+(get_random16()%5000))) {
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// total loss of signal for a period at the start is common
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d.num_sats = 0;
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d.have_lock = false;
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} else {
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if ((now_ms - jam.last_sats_change_ms)*0.001 > 2*fabsf(rand_float())/sats_change_hz) {
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jam.last_sats_change_ms = now_ms;
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d.num_sats = 2 + (get_random16() % 15);
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if (d.num_sats >= 4) {
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if (get_random16() % 2 == 0) {
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d.have_lock = false;
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} else {
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d.have_lock = true;
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}
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} else {
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d.have_lock = false;
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}
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}
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if ((now_ms - jam.last_vz_change_ms)*0.001 > 2*fabsf(rand_float())/vz_change_hz) {
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jam.last_vz_change_ms = now_ms;
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d.speedD = rand_float() * 400;
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}
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if ((now_ms - jam.last_vel_change_ms)*0.001 > 2*fabsf(rand_float())/vel_change_hz) {
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jam.last_vel_change_ms = now_ms;
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d.speedN = rand_float() * 400;
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d.speedE = rand_float() * 400;
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}
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if ((now_ms - jam.last_pos_change_ms)*0.001 > 2*fabsf(rand_float())/pos_change_hz) {
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jam.last_pos_change_ms = now_ms;
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jam.latitude += rand_float()*200 * LATLON_TO_M_INV * 1e-7;
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jam.longitude += rand_float()*200 * LATLON_TO_M_INV * 1e-7;
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}
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if ((now_ms - jam.last_acc_change_ms)*0.001 > 2*fabsf(rand_float())/acc_change_hz) {
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jam.last_acc_change_ms = now_ms;
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d.vertical_acc = fabsf(rand_float())*300;
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d.horizontal_acc = fabsf(rand_float())*300;
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d.speed_acc = fabsf(rand_float())*50;
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}
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}
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d.latitude = constrain_float(jam.latitude, -90, 90);
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d.longitude = constrain_float(jam.longitude, -180, 180);
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}
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/*
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return GPS time of week
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*/
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GPS_Backend::GPS_TOW GPS_Backend::gps_time()
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{
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GPS_TOW gps_tow;
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struct timeval tv;
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simulation_timeval(&tv);
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const uint32_t epoch = 86400*(10*365 + (1980-1969)/4 + 1 + 6 - 2) - (GPS_LEAPSECONDS_MILLIS / 1000ULL);
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uint32_t epoch_seconds = tv.tv_sec - epoch;
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gps_tow.week = epoch_seconds / AP_SEC_PER_WEEK;
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uint32_t t_ms = tv.tv_usec / 1000;
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// round time to nearest 200ms
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gps_tow.ms = (epoch_seconds % AP_SEC_PER_WEEK) * AP_MSEC_PER_SEC + ((t_ms/200) * 200);
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return gps_tow;
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}
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void GPS::check_backend_allocation()
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{
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const Type configured_type = Type(_sitl->gps_type[instance].get());
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if (allocated_type == configured_type) {
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return;
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}
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// mismatch; delete any already-allocated backend:
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if (backend != nullptr) {
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delete backend;
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backend = nullptr;
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}
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// attempt to allocate backend
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switch (configured_type) {
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case Type::NONE:
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// no GPS attached
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break;
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#if AP_SIM_GPS_UBLOX_ENABLED
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case Type::UBLOX:
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backend = new GPS_UBlox(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_NMEA_ENABLED
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case Type::NMEA:
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backend = new GPS_NMEA(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_SBP_ENABLED
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case Type::SBP:
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backend = new GPS_SBP(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_SBP2_ENABLED
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case Type::SBP2:
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backend = new GPS_SBP2(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_NOVA_ENABLED
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case Type::NOVA:
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backend = new GPS_NOVA(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_MSP_ENABLED
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case Type::MSP:
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backend = new GPS_MSP(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_TRIMBLE_ENABLED
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case Type::TRIMBLE:
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backend = new GPS_Trimble(*this, instance);
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break;
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#endif
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#if AP_SIM_GPS_FILE_ENABLED
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case Type::FILE:
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backend = new GPS_FILE(*this, instance);
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break;
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#endif
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};
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allocated_type = configured_type;
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}
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/*
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possibly send a new GPS packet
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*/
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void GPS::update()
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{
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if (!init_sitl_pointer()) {
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return;
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}
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check_backend_allocation();
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if (backend == nullptr) {
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return;
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}
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double latitude =_sitl->state.latitude;
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double longitude = _sitl->state.longitude;
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float altitude = _sitl->state.altitude;
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const double speedN = _sitl->state.speedN;
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const double speedE = _sitl->state.speedE;
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const double speedD = _sitl->state.speedD;
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const uint32_t now_ms = AP_HAL::millis();
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if (now_ms < 20000) {
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// apply the init offsets for the first 20s. This allows for
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// having the origin a long way from the takeoff location,
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// which makes testing long flights easier
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latitude += _sitl->gps_init_lat_ofs;
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longitude += _sitl->gps_init_lon_ofs;
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altitude += _sitl->gps_init_alt_ofs;
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}
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//Capture current position as basestation location for
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if (!_gps_has_basestation_position &&
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now_ms >= _sitl->gps_lock_time[0]*1000UL) {
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_gps_basestation_data.latitude = latitude;
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_gps_basestation_data.longitude = longitude;
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_gps_basestation_data.altitude = altitude;
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_gps_basestation_data.speedN = speedN;
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_gps_basestation_data.speedE = speedE;
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_gps_basestation_data.speedD = speedD;
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_gps_has_basestation_position = true;
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}
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const uint8_t idx = instance; // alias to avoid code churn
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struct GPS_Data d {};
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// simulate delayed lock times
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bool have_lock = (!_sitl->gps_disable[idx] && now_ms >= _sitl->gps_lock_time[idx]*1000UL);
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// Only let physics run and GPS write at configured GPS rate (default 5Hz).
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if ((now_ms - last_write_update_ms) < (uint32_t)(1000/_sitl->gps_hertz[instance])) {
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// Reading runs every iteration.
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// Beware- physics don't update every iteration with this approach.
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// Currently, none of the drivers rely on quickly updated physics.
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backend->update_read();
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return;
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}
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last_write_update_ms = now_ms;
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d.latitude = latitude;
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d.longitude = longitude;
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d.yaw_deg = _sitl->state.yawDeg;
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d.roll_deg = _sitl->state.rollDeg;
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d.pitch_deg = _sitl->state.pitchDeg;
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// add an altitude error controlled by a slow sine wave
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d.altitude = altitude + _sitl->gps_noise[idx] * sinf(now_ms * 0.0005f) + _sitl->gps_alt_offset[idx];
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// Add offset to c.g. velocity to get velocity at antenna and add simulated error
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Vector3f velErrorNED = _sitl->gps_vel_err[idx];
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d.speedN = speedN + (velErrorNED.x * rand_float());
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d.speedE = speedE + (velErrorNED.y * rand_float());
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d.speedD = speedD + (velErrorNED.z * rand_float());
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d.have_lock = have_lock;
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if (_sitl->gps_drift_alt[idx] > 0) {
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// add slow altitude drift controlled by a slow sine wave
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d.altitude += _sitl->gps_drift_alt[idx]*sinf(now_ms*0.001f*0.02f);
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}
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// correct the latitude, longitude, height and NED velocity for the offset between
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// the vehicle c.g. and GPS antenna
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Vector3f posRelOffsetBF = _sitl->gps_pos_offset[idx];
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if (!posRelOffsetBF.is_zero()) {
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// get a rotation matrix following DCM conventions (body to earth)
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Matrix3f rotmat;
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_sitl->state.quaternion.rotation_matrix(rotmat);
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// rotate the antenna offset into the earth frame
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Vector3f posRelOffsetEF = rotmat * posRelOffsetBF;
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// Add the offset to the latitude, longitude and height using a spherical earth approximation
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double const earth_rad_inv = 1.569612305760477e-7; // use Authalic/Volumetric radius
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double lng_scale_factor = earth_rad_inv / cos(radians(d.latitude));
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d.latitude += degrees(posRelOffsetEF.x * earth_rad_inv);
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d.longitude += degrees(posRelOffsetEF.y * lng_scale_factor);
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d.altitude -= posRelOffsetEF.z;
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// calculate a velocity offset due to the antenna position offset and body rotation rate
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// note: % operator is overloaded for cross product
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Vector3f gyro(radians(_sitl->state.rollRate),
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radians(_sitl->state.pitchRate),
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radians(_sitl->state.yawRate));
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Vector3f velRelOffsetBF = gyro % posRelOffsetBF;
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// rotate the velocity offset into earth frame and add to the c.g. velocity
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Vector3f velRelOffsetEF = rotmat * velRelOffsetBF;
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d.speedN += velRelOffsetEF.x;
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d.speedE += velRelOffsetEF.y;
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d.speedD += velRelOffsetEF.z;
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}
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// get delayed data
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d.timestamp_ms = now_ms;
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d = interpolate_data(d, _sitl->gps_delay_ms[instance]);
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// Applying GPS glitch
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// Using first gps glitch
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Vector3f glitch_offsets = _sitl->gps_glitch[idx];
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d.latitude += glitch_offsets.x;
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d.longitude += glitch_offsets.y;
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d.altitude += glitch_offsets.z;
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if (_sitl->gps_jam[idx] == 1) {
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simulate_jamming(d);
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}
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backend->publish(&d);
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}
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void GPS_Backend::update_read()
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{
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// swallow any config bytes
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char c;
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read_from_autopilot(&c, 1);
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}
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/*
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get delayed data by interpolation
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*/
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GPS_Data GPS::interpolate_data(const GPS_Data &d, uint32_t delay_ms)
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{
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const uint8_t N = ARRAY_SIZE(_gps_history);
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const uint32_t now_ms = d.timestamp_ms;
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// add in into history array, shifting old elements
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memmove(&_gps_history[1], &_gps_history[0], sizeof(_gps_history[0])*(ARRAY_SIZE(_gps_history)-1));
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_gps_history[0] = d;
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for (uint8_t i=0; i<N-1; i++) {
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uint32_t dt1 = now_ms - _gps_history[i].timestamp_ms;
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uint32_t dt2 = now_ms - _gps_history[i+1].timestamp_ms;
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if (delay_ms >= dt1 && delay_ms <= dt2) {
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// we will interpolate this pair of samples. Start with
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// the older sample
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const GPS_Data &s1 = _gps_history[i+1];
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const GPS_Data &s2 = _gps_history[i];
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GPS_Data d2 = s1;
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const float p = (dt2 - delay_ms) / MAX(1,float(dt2 - dt1));
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d2.latitude += p * (s2.latitude - s1.latitude);
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d2.longitude += p * (s2.longitude - s1.longitude);
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d2.altitude += p * (s2.altitude - s1.altitude);
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d2.speedN += p * (s2.speedN - s1.speedN);
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d2.speedE += p * (s2.speedE - s1.speedE);
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d2.speedD += p * (s2.speedD - s1.speedD);
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d2.yaw_deg += p * wrap_180(s2.yaw_deg - s1.yaw_deg);
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return d2;
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}
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}
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// delay is too long, use last sample
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return _gps_history[N-1];
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}
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float GPS_Data::ground_track_rad() const
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{
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return atan2f(speedE, speedN);
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}
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float GPS_Data::speed_2d() const
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{
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const auto velocity = Vector2d{speedN, speedE};
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return velocity.length();
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}
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#endif // HAL_SIM_GPS_ENABLED
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