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gnss-sdr/src/algorithms/PVT/libs/rtklib_solver.cc

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/*!
* \file rtklib_solver.cc
* \brief PVT solver based on rtklib library functions adapted to the GNSS-SDR
* data flow and structures
* \authors <ul>
* <li> 2017, Javier Arribas
* <li> 2017, Carles Fernandez
* <li> 2007-2013, T. Takasu
* </ul>
*
* This is a derived work from RTKLIB http://www.rtklib.com/
* The original source code at https://github.com/tomojitakasu/RTKLIB is
* released under the BSD 2-clause license with an additional exclusive clause
* that does not apply here. This additional clause is reproduced below:
*
* " The software package includes some companion executive binaries or shared
* libraries necessary to execute APs on Windows. These licenses succeed to the
* original ones of these software. "
*
* Neither the executive binaries nor the shared libraries are required by, used
* or included in GNSS-SDR.
*
* -------------------------------------------------------------------------
* Copyright (C) 2007-2013, T. Takasu
* Copyright (C) 2017, Javier Arribas
* Copyright (C) 2017, Carles Fernandez
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* -----------------------------------------------------------------------*/
#include "rtklib_solver.h"
#include "Beidou_B1I.h"
#include "GLONASS_L1_L2_CA.h"
#include "GPS_L1_CA.h"
#include "Galileo_E1.h"
#include "rtklib_conversions.h"
#include "rtklib_solution.h"
#include <glog/logging.h>
#include <matio.h>
#include <exception>
#include <utility>
using google::LogMessage;
Rtklib_Solver::Rtklib_Solver(int nchannels, std::string dump_filename, bool flag_dump_to_file, bool flag_dump_to_mat, const rtk_t &rtk)
{
// init empty ephemeris for all the available GNSS channels
d_nchannels = nchannels;
d_dump_filename = std::move(dump_filename);
d_flag_dump_enabled = flag_dump_to_file;
d_flag_dump_mat_enabled = flag_dump_to_mat;
count_valid_position = 0;
this->set_averaging_flag(false);
rtk_ = rtk;
for (double &i : dop_)
{
i = 0.0;
}
pvt_sol = {{0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, '0', '0', '0', 0, 0, 0};
ssat_t ssat0 = {0, 0, {0.0}, {0.0}, {0.0}, {'0'}, {'0'}, {'0'}, {'0'}, {'0'}, {}, {}, {}, {}, 0.0, 0.0, 0.0, 0.0, {{{0, 0}}, {{0, 0}}}, {{}, {}}};
for (auto &i : pvt_ssat)
{
i = ssat0;
}
// ############# ENABLE DATA FILE LOG #################
if (d_flag_dump_enabled == true)
{
if (d_dump_file.is_open() == false)
{
try
{
d_dump_file.exceptions(std::ofstream::failbit | std::ofstream::badbit);
d_dump_file.open(d_dump_filename.c_str(), std::ios::out | std::ios::binary);
LOG(INFO) << "PVT lib dump enabled Log file: " << d_dump_filename.c_str();
}
catch (const std::ofstream::failure &e)
{
LOG(WARNING) << "Exception opening RTKLIB dump file " << e.what();
}
}
}
// PVT MONITOR
monitor_pvt.TOW_at_current_symbol_ms = 0U;
monitor_pvt.week = 0U;
monitor_pvt.RX_time = 0.0;
monitor_pvt.user_clk_offset = 0.0;
monitor_pvt.pos_x = 0.0;
monitor_pvt.pos_y = 0.0;
monitor_pvt.pos_z = 0.0;
monitor_pvt.vel_x = 0.0;
monitor_pvt.vel_y = 0.0;
monitor_pvt.vel_z = 0.0;
monitor_pvt.cov_xx = 0.0;
monitor_pvt.cov_yy = 0.0;
monitor_pvt.cov_zz = 0.0;
monitor_pvt.cov_xy = 0.0;
monitor_pvt.cov_yz = 0.0;
monitor_pvt.cov_zx = 0.0;
monitor_pvt.latitude = 0.0;
monitor_pvt.longitude = 0.0;
monitor_pvt.height = 0.0;
monitor_pvt.valid_sats = 0;
monitor_pvt.solution_status = 0;
monitor_pvt.solution_type = 0;
monitor_pvt.AR_ratio_factor = 0.0;
monitor_pvt.AR_ratio_threshold = 0.0;
monitor_pvt.gdop = 0.0;
monitor_pvt.pdop = 0.0;
monitor_pvt.hdop = 0.0;
monitor_pvt.vdop = 0.0;
}
bool Rtklib_Solver::save_matfile()
{
// READ DUMP FILE
std::string dump_filename = d_dump_filename;
std::ifstream::pos_type size;
int32_t number_of_double_vars = 21;
int32_t number_of_uint32_vars = 2;
int32_t number_of_uint8_vars = 3;
int32_t number_of_float_vars = 2;
int32_t epoch_size_bytes = sizeof(double) * number_of_double_vars +
sizeof(uint32_t) * number_of_uint32_vars +
sizeof(uint8_t) * number_of_uint8_vars +
sizeof(float) * number_of_float_vars;
std::ifstream dump_file;
std::cout << "Generating .mat file for " << dump_filename << std::endl;
dump_file.exceptions(std::ifstream::failbit | std::ifstream::badbit);
try
{
dump_file.open(dump_filename.c_str(), std::ios::binary | std::ios::ate);
}
catch (const std::ifstream::failure &e)
{
std::cerr << "Problem opening dump file:" << e.what() << std::endl;
return false;
}
// count number of epochs and rewind
int64_t num_epoch = 0LL;
if (dump_file.is_open())
{
size = dump_file.tellg();
num_epoch = static_cast<int64_t>(size) / static_cast<int64_t>(epoch_size_bytes);
dump_file.seekg(0, std::ios::beg);
}
else
{
return false;
}
auto *TOW_at_current_symbol_ms = new uint32_t[num_epoch];
auto *week = new uint32_t[num_epoch];
auto *RX_time = new double[num_epoch];
auto *user_clk_offset = new double[num_epoch];
auto *pos_x = new double[num_epoch];
auto *pos_y = new double[num_epoch];
auto *pos_z = new double[num_epoch];
auto *vel_x = new double[num_epoch];
auto *vel_y = new double[num_epoch];
auto *vel_z = new double[num_epoch];
auto *cov_xx = new double[num_epoch];
auto *cov_yy = new double[num_epoch];
auto *cov_zz = new double[num_epoch];
auto *cov_xy = new double[num_epoch];
auto *cov_yz = new double[num_epoch];
auto *cov_zx = new double[num_epoch];
auto *latitude = new double[num_epoch];
auto *longitude = new double[num_epoch];
auto *height = new double[num_epoch];
auto *valid_sats = new uint8_t[num_epoch];
auto *solution_status = new uint8_t[num_epoch];
auto *solution_type = new uint8_t[num_epoch];
auto *AR_ratio_factor = new float[num_epoch];
auto *AR_ratio_threshold = new float[num_epoch];
auto *gdop = new double[num_epoch];
auto *pdop = new double[num_epoch];
auto *hdop = new double[num_epoch];
auto *vdop = new double[num_epoch];
try
{
if (dump_file.is_open())
{
for (int64_t i = 0; i < num_epoch; i++)
{
dump_file.read(reinterpret_cast<char *>(&TOW_at_current_symbol_ms[i]), sizeof(uint32_t));
dump_file.read(reinterpret_cast<char *>(&week[i]), sizeof(uint32_t));
dump_file.read(reinterpret_cast<char *>(&RX_time[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&user_clk_offset[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&pos_x[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&pos_y[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&pos_z[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&vel_x[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&vel_y[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&vel_z[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&cov_xx[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&cov_yy[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&cov_zz[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&cov_xy[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&cov_yz[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&cov_zx[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&latitude[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&longitude[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&height[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&valid_sats[i]), sizeof(uint8_t));
dump_file.read(reinterpret_cast<char *>(&solution_status[i]), sizeof(uint8_t));
dump_file.read(reinterpret_cast<char *>(&solution_type[i]), sizeof(uint8_t));
dump_file.read(reinterpret_cast<char *>(&AR_ratio_factor[i]), sizeof(float));
dump_file.read(reinterpret_cast<char *>(&AR_ratio_threshold[i]), sizeof(float));
dump_file.read(reinterpret_cast<char *>(&gdop[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&pdop[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&hdop[i]), sizeof(double));
dump_file.read(reinterpret_cast<char *>(&vdop[i]), sizeof(double));
}
}
dump_file.close();
}
catch (const std::ifstream::failure &e)
{
std::cerr << "Problem reading dump file:" << e.what() << std::endl;
delete[] TOW_at_current_symbol_ms;
delete[] week;
delete[] RX_time;
delete[] user_clk_offset;
delete[] pos_x;
delete[] pos_y;
delete[] pos_z;
delete[] vel_x;
delete[] vel_y;
delete[] vel_z;
delete[] cov_xx;
delete[] cov_yy;
delete[] cov_zz;
delete[] cov_xy;
delete[] cov_yz;
delete[] cov_zx;
delete[] latitude;
delete[] longitude;
delete[] height;
delete[] valid_sats;
delete[] solution_status;
delete[] solution_type;
delete[] AR_ratio_factor;
delete[] AR_ratio_threshold;
delete[] gdop;
delete[] pdop;
delete[] hdop;
delete[] vdop;
return false;
}
// WRITE MAT FILE
mat_t *matfp;
matvar_t *matvar;
std::string filename = dump_filename;
filename.erase(filename.length() - 4, 4);
filename.append(".mat");
matfp = Mat_CreateVer(filename.c_str(), nullptr, MAT_FT_MAT73);
if (reinterpret_cast<int64_t *>(matfp) != nullptr)
{
size_t dims[2] = {1, static_cast<size_t>(num_epoch)};
matvar = Mat_VarCreate("TOW_at_current_symbol_ms", MAT_C_UINT32, MAT_T_UINT32, 2, dims, TOW_at_current_symbol_ms, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("week", MAT_C_UINT32, MAT_T_UINT32, 2, dims, week, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("RX_time", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, RX_time, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("user_clk_offset", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, user_clk_offset, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("pos_x", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, pos_x, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("pos_y", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, pos_y, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("pos_z", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, pos_z, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("vel_x", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, vel_x, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("vel_y", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, vel_y, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("vel_z", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, vel_z, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("cov_xx", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, cov_xx, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("cov_yy", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, cov_yy, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("cov_zz", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, cov_zz, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("cov_xy", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, cov_xy, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("cov_yz", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, cov_yz, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("cov_zx", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, cov_zx, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("latitude", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, latitude, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("longitude", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, longitude, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("height", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, height, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("valid_sats", MAT_C_UINT8, MAT_T_UINT8, 2, dims, valid_sats, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("solution_status", MAT_C_UINT8, MAT_T_UINT8, 2, dims, solution_status, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("solution_type", MAT_C_UINT8, MAT_T_UINT8, 2, dims, solution_type, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("AR_ratio_factor", MAT_C_SINGLE, MAT_T_SINGLE, 2, dims, AR_ratio_factor, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("AR_ratio_threshold", MAT_C_SINGLE, MAT_T_SINGLE, 2, dims, AR_ratio_threshold, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("gdop", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, gdop, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("pdop", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, pdop, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("hdop", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, hdop, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
matvar = Mat_VarCreate("vdop", MAT_C_DOUBLE, MAT_T_DOUBLE, 2, dims, vdop, 0);
Mat_VarWrite(matfp, matvar, MAT_COMPRESSION_ZLIB); // or MAT_COMPRESSION_NONE
Mat_VarFree(matvar);
}
Mat_Close(matfp);
delete[] TOW_at_current_symbol_ms;
delete[] week;
delete[] RX_time;
delete[] user_clk_offset;
delete[] pos_x;
delete[] pos_y;
delete[] pos_z;
delete[] vel_x;
delete[] vel_y;
delete[] vel_z;
delete[] cov_xx;
delete[] cov_yy;
delete[] cov_zz;
delete[] cov_xy;
delete[] cov_yz;
delete[] cov_zx;
delete[] latitude;
delete[] longitude;
delete[] height;
delete[] valid_sats;
delete[] solution_status;
delete[] solution_type;
delete[] AR_ratio_factor;
delete[] AR_ratio_threshold;
delete[] gdop;
delete[] pdop;
delete[] hdop;
delete[] vdop;
return true;
}
Rtklib_Solver::~Rtklib_Solver()
{
if (d_dump_file.is_open() == true)
{
try
{
d_dump_file.close();
}
catch (const std::exception &ex)
{
LOG(WARNING) << "Exception in destructor closing the RTKLIB dump file " << ex.what();
}
}
if (d_flag_dump_mat_enabled)
{
try
{
save_matfile();
}
catch (const std::exception &ex)
{
LOG(WARNING) << "Exception in destructor saving the PVT .mat dump file " << ex.what();
}
}
}
double Rtklib_Solver::get_gdop() const
{
return dop_[0];
}
double Rtklib_Solver::get_pdop() const
{
return dop_[1];
}
double Rtklib_Solver::get_hdop() const
{
return dop_[2];
}
double Rtklib_Solver::get_vdop() const
{
return dop_[3];
}
Monitor_Pvt Rtklib_Solver::get_monitor_pvt() const
{
return monitor_pvt;
}
bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_map, bool flag_averaging)
{
std::map<int, Gnss_Synchro>::const_iterator gnss_observables_iter;
std::map<int, Galileo_Ephemeris>::const_iterator galileo_ephemeris_iter;
std::map<int, Gps_Ephemeris>::const_iterator gps_ephemeris_iter;
std::map<int, Gps_CNAV_Ephemeris>::const_iterator gps_cnav_ephemeris_iter;
std::map<int, Glonass_Gnav_Ephemeris>::const_iterator glonass_gnav_ephemeris_iter;
std::map<int, Beidou_Dnav_Ephemeris>::const_iterator beidou_ephemeris_iter;
const Glonass_Gnav_Utc_Model gnav_utc = this->glonass_gnav_utc_model;
this->set_averaging_flag(flag_averaging);
// ********************************************************************************
// ****** PREPARE THE DATA (SV EPHEMERIS AND OBSERVATIONS) ************************
// ********************************************************************************
int valid_obs = 0; // valid observations counter
int glo_valid_obs = 0; // GLONASS L1/L2 valid observations counter
obsd_t obs_data[MAXOBS];
eph_t eph_data[MAXOBS];
geph_t geph_data[MAXOBS];
// Workaround for NAV/CNAV clash problem
bool gps_dual_band = false;
bool band1 = false;
bool band2 = false;
for (gnss_observables_iter = gnss_observables_map.cbegin();
gnss_observables_iter != gnss_observables_map.cend();
++gnss_observables_iter)
{
switch (gnss_observables_iter->second.System)
{
case 'G':
{
std::string sig_(gnss_observables_iter->second.Signal);
if (sig_ == "1C")
{
band1 = true;
}
if (sig_ == "2S")
{
band2 = true;
}
}
break;
default:
{
}
}
}
if (band1 == true and band2 == true)
{
gps_dual_band = true;
}
for (gnss_observables_iter = gnss_observables_map.cbegin();
gnss_observables_iter != gnss_observables_map.cend();
++gnss_observables_iter) // CHECK INCONSISTENCY when combining GLONASS + other system
{
switch (gnss_observables_iter->second.System)
{
case 'E':
{
std::string sig_(gnss_observables_iter->second.Signal);
// Galileo E1
if (sig_ == "1B")
{
// 1 Gal - find the ephemeris for the current GALILEO SV observation. The SV PRN ID is the map key
galileo_ephemeris_iter = galileo_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (galileo_ephemeris_iter != galileo_ephemeris_map.cend())
{
// convert ephemeris from GNSS-SDR class to RTKLIB structure
eph_data[valid_obs] = eph_to_rtklib(galileo_ephemeris_iter->second);
// convert observation from GNSS-SDR class to RTKLIB structure
obsd_t newobs = {{0, 0}, '0', '0', {}, {}, {}, {}, {}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
galileo_ephemeris_iter->second.WN_5,
0);
valid_obs++;
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->second.PRN;
}
}
// Galileo E5
if (sig_ == "5X")
{
// 1 Gal - find the ephemeris for the current GALILEO SV observation. The SV PRN ID is the map key
galileo_ephemeris_iter = galileo_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (galileo_ephemeris_iter != galileo_ephemeris_map.cend())
{
bool found_E1_obs = false;
for (int i = 0; i < valid_obs; i++)
{
if (eph_data[i].sat == (static_cast<int>(gnss_observables_iter->second.PRN + NSATGPS + NSATGLO)))
{
obs_data[i + glo_valid_obs] = insert_obs_to_rtklib(obs_data[i + glo_valid_obs],
gnss_observables_iter->second,
galileo_ephemeris_iter->second.WN_5,
2); // Band 3 (L5/E5)
found_E1_obs = true;
break;
}
}
if (!found_E1_obs)
{
// insert Galileo E5 obs as new obs and also insert its ephemeris
// convert ephemeris from GNSS-SDR class to RTKLIB structure
eph_data[valid_obs] = eph_to_rtklib(galileo_ephemeris_iter->second);
// convert observation from GNSS-SDR class to RTKLIB structure
auto default_code_ = static_cast<unsigned char>(CODE_NONE);
obsd_t newobs = {{0, 0}, '0', '0', {}, {},
{default_code_, default_code_, default_code_},
{}, {0.0, 0.0, 0.0}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
galileo_ephemeris_iter->second.WN_5,
2); // Band 3 (L5/E5)
valid_obs++;
}
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->second.PRN;
}
}
break;
}
case 'G':
{
// GPS L1
// 1 GPS - find the ephemeris for the current GPS SV observation. The SV PRN ID is the map key
std::string sig_(gnss_observables_iter->second.Signal);
if (sig_ == "1C")
{
gps_ephemeris_iter = gps_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (gps_ephemeris_iter != gps_ephemeris_map.cend())
{
// convert ephemeris from GNSS-SDR class to RTKLIB structure
eph_data[valid_obs] = eph_to_rtklib(gps_ephemeris_iter->second);
// convert observation from GNSS-SDR class to RTKLIB structure
obsd_t newobs = {{0, 0}, '0', '0', {}, {}, {}, {}, {}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
gps_ephemeris_iter->second.i_GPS_week,
0);
valid_obs++;
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->first;
}
}
// GPS L2 (todo: solve NAV/CNAV clash)
if ((sig_ == "2S") and (gps_dual_band == false))
{
gps_cnav_ephemeris_iter = gps_cnav_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (gps_cnav_ephemeris_iter != gps_cnav_ephemeris_map.cend())
{
// 1. Find the same satellite in GPS L1 band
gps_ephemeris_iter = gps_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (gps_ephemeris_iter != gps_ephemeris_map.cend())
{
/* By the moment, GPS L2 observables are not used in pseudorange computations if GPS L1 is available
// 2. If found, replace the existing GPS L1 ephemeris with the GPS L2 ephemeris
// (more precise!), and attach the L2 observation to the L1 observation in RTKLIB structure
for (int i = 0; i < valid_obs; i++)
{
if (eph_data[i].sat == static_cast<int>(gnss_observables_iter->second.PRN))
{
eph_data[i] = eph_to_rtklib(gps_cnav_ephemeris_iter->second);
obs_data[i + glo_valid_obs] = insert_obs_to_rtklib(obs_data[i + glo_valid_obs],
gnss_observables_iter->second,
eph_data[i].week,
1); // Band 2 (L2)
break;
}
}
*/
}
else
{
// 3. If not found, insert the GPS L2 ephemeris and the observation
// convert ephemeris from GNSS-SDR class to RTKLIB structure
eph_data[valid_obs] = eph_to_rtklib(gps_cnav_ephemeris_iter->second);
// convert observation from GNSS-SDR class to RTKLIB structure
auto default_code_ = static_cast<unsigned char>(CODE_NONE);
obsd_t newobs = {{0, 0}, '0', '0', {}, {},
{default_code_, default_code_, default_code_},
{}, {0.0, 0.0, 0.0}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
gps_cnav_ephemeris_iter->second.i_GPS_week,
1); // Band 2 (L2)
valid_obs++;
}
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->second.PRN;
}
}
// GPS L5
if (sig_ == "L5")
{
gps_cnav_ephemeris_iter = gps_cnav_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (gps_cnav_ephemeris_iter != gps_cnav_ephemeris_map.cend())
{
// 1. Find the same satellite in GPS L1 band
gps_ephemeris_iter = gps_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (gps_ephemeris_iter != gps_ephemeris_map.cend())
{
// 2. If found, replace the existing GPS L1 ephemeris with the GPS L5 ephemeris
// (more precise!), and attach the L5 observation to the L1 observation in RTKLIB structure
for (int i = 0; i < valid_obs; i++)
{
if (eph_data[i].sat == static_cast<int>(gnss_observables_iter->second.PRN))
{
eph_data[i] = eph_to_rtklib(gps_cnav_ephemeris_iter->second);
obs_data[i + glo_valid_obs] = insert_obs_to_rtklib(obs_data[i],
gnss_observables_iter->second,
gps_cnav_ephemeris_iter->second.i_GPS_week,
2); // Band 3 (L5)
break;
}
}
}
else
{
// 3. If not found, insert the GPS L5 ephemeris and the observation
// convert ephemeris from GNSS-SDR class to RTKLIB structure
eph_data[valid_obs] = eph_to_rtklib(gps_cnav_ephemeris_iter->second);
// convert observation from GNSS-SDR class to RTKLIB structure
auto default_code_ = static_cast<unsigned char>(CODE_NONE);
obsd_t newobs = {{0, 0}, '0', '0', {}, {},
{default_code_, default_code_, default_code_},
{}, {0.0, 0.0, 0.0}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
gps_cnav_ephemeris_iter->second.i_GPS_week,
2); // Band 3 (L5)
valid_obs++;
}
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->second.PRN;
}
}
break;
}
case 'R': //TODO This should be using rtk lib nomenclature
{
std::string sig_(gnss_observables_iter->second.Signal);
// GLONASS GNAV L1
if (sig_ == "1G")
{
// 1 Glo - find the ephemeris for the current GLONASS SV observation. The SV Slot Number (PRN ID) is the map key
glonass_gnav_ephemeris_iter = glonass_gnav_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (glonass_gnav_ephemeris_iter != glonass_gnav_ephemeris_map.cend())
{
// convert ephemeris from GNSS-SDR class to RTKLIB structure
geph_data[glo_valid_obs] = eph_to_rtklib(glonass_gnav_ephemeris_iter->second, gnav_utc);
// convert observation from GNSS-SDR class to RTKLIB structure
obsd_t newobs = {{0, 0}, '0', '0', {}, {}, {}, {}, {}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
glonass_gnav_ephemeris_iter->second.d_WN,
0); // Band 0 (L1)
glo_valid_obs++;
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->second.PRN;
}
}
// GLONASS GNAV L2
if (sig_ == "2G")
{
// 1 GLONASS - find the ephemeris for the current GLONASS SV observation. The SV PRN ID is the map key
glonass_gnav_ephemeris_iter = glonass_gnav_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (glonass_gnav_ephemeris_iter != glonass_gnav_ephemeris_map.cend())
{
bool found_L1_obs = false;
for (int i = 0; i < glo_valid_obs; i++)
{
if (geph_data[i].sat == (static_cast<int>(gnss_observables_iter->second.PRN + NSATGPS)))
{
obs_data[i + valid_obs] = insert_obs_to_rtklib(obs_data[i + valid_obs],
gnss_observables_iter->second,
glonass_gnav_ephemeris_iter->second.d_WN,
1); //Band 1 (L2)
found_L1_obs = true;
break;
}
}
if (!found_L1_obs)
{
// insert GLONASS GNAV L2 obs as new obs and also insert its ephemeris
// convert ephemeris from GNSS-SDR class to RTKLIB structure
geph_data[glo_valid_obs] = eph_to_rtklib(glonass_gnav_ephemeris_iter->second, gnav_utc);
// convert observation from GNSS-SDR class to RTKLIB structure
obsd_t newobs = {{0, 0}, '0', '0', {}, {}, {}, {}, {}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
glonass_gnav_ephemeris_iter->second.d_WN,
1); // Band 1 (L2)
glo_valid_obs++;
}
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->second.PRN;
}
}
break;
}
case 'C':
{
// BEIDOU B1I
// - find the ephemeris for the current BEIDOU SV observation. The SV PRN ID is the map key
std::string sig_(gnss_observables_iter->second.Signal);
if (sig_ == "B1")
{
beidou_ephemeris_iter = beidou_dnav_ephemeris_map.find(gnss_observables_iter->second.PRN);
if (beidou_ephemeris_iter != beidou_dnav_ephemeris_map.cend())
{
// convert ephemeris from GNSS-SDR class to RTKLIB structure
eph_data[valid_obs] = eph_to_rtklib(beidou_ephemeris_iter->second);
// convert observation from GNSS-SDR class to RTKLIB structure
obsd_t newobs = {{0, 0}, '0', '0', {}, {}, {}, {}, {}, {}};
obs_data[valid_obs + glo_valid_obs] = insert_obs_to_rtklib(newobs,
gnss_observables_iter->second,
beidou_ephemeris_iter->second.i_BEIDOU_week + 1356,
0);
valid_obs++;
}
else // the ephemeris are not available for this SV
{
DLOG(INFO) << "No ephemeris data for SV " << gnss_observables_iter->first;
}
}
break;
}
default:
DLOG(INFO) << "Hybrid observables: Unknown GNSS";
break;
}
}
// **********************************************************************
// ****** SOLVE PVT******************************************************
// **********************************************************************
this->set_valid_position(false);
if ((valid_obs + glo_valid_obs) > 3)
{
int result = 0;
nav_t nav_data;
nav_data.eph = eph_data;
nav_data.geph = geph_data;
nav_data.n = valid_obs;
nav_data.ng = glo_valid_obs;
for (auto &i : nav_data.lam)
{
i[0] = SPEED_OF_LIGHT / FREQ1; // L1/E1
i[1] = SPEED_OF_LIGHT / FREQ2; // L2
i[2] = SPEED_OF_LIGHT / FREQ5; // L5/E5
}
result = rtkpos(&rtk_, obs_data, valid_obs + glo_valid_obs, &nav_data);
if (result == 0)
{
LOG(INFO) << "RTKLIB rtkpos error";
DLOG(INFO) << "RTKLIB rtkpos error message: " << rtk_.errbuf;
this->set_time_offset_s(0.0); // reset rx time estimation
this->set_num_valid_observations(0);
}
else
{
this->set_num_valid_observations(rtk_.sol.ns); // record the number of valid satellites used by the PVT solver
pvt_sol = rtk_.sol;
// DOP computation
unsigned int used_sats = 0;
for (unsigned int i = 0; i < MAXSAT; i++)
{
pvt_ssat[i] = rtk_.ssat[i];
if (rtk_.ssat[i].vs == 1)
{
used_sats++;
}
}
std::vector<double> azel;
azel.reserve(used_sats * 2);
unsigned int index_aux = 0;
for (auto &i : rtk_.ssat)
{
if (i.vs == 1)
{
azel[2 * index_aux] = i.azel[0];
azel[2 * index_aux + 1] = i.azel[1];
index_aux++;
}
}
if (index_aux > 0)
{
dops(index_aux, azel.data(), 0.0, dop_.data());
}
this->set_valid_position(true);
arma::vec rx_position_and_time(4);
rx_position_and_time(0) = pvt_sol.rr[0]; // [m]
rx_position_and_time(1) = pvt_sol.rr[1]; // [m]
rx_position_and_time(2) = pvt_sol.rr[2]; // [m]
//todo: fix this ambiguity in the RTKLIB units in receiver clock offset!
if (rtk_.opt.mode == PMODE_SINGLE)
{
rx_position_and_time(3) = pvt_sol.dtr[0]; // if the RTKLIB solver is set to SINGLE, the dtr is already expressed in [s]
}
else
{
rx_position_and_time(3) = pvt_sol.dtr[0] / GPS_C_M_S; // the receiver clock offset is expressed in [meters], so we convert it into [s]
}
this->set_rx_pos(rx_position_and_time.rows(0, 2)); // save ECEF position for the next iteration
//compute Ground speed and COG
double ground_speed_ms = 0.0;
double pos[3];
double enuv[3];
ecef2pos(pvt_sol.rr, pos);
ecef2enu(pos, &pvt_sol.rr[3], enuv);
this->set_speed_over_ground(norm_rtk(enuv, 2));
double new_cog;
if (ground_speed_ms >= 1.0)
{
new_cog = atan2(enuv[0], enuv[1]) * R2D;
if (new_cog < 0.0)
{
new_cog += 360.0;
}
this->set_course_over_ground(new_cog);
}
//observable fix:
//double offset_s = this->get_time_offset_s();
//this->set_time_offset_s(offset_s + (rx_position_and_time(3) / GPS_C_m_s)); // accumulate the rx time error for the next iteration [meters]->[seconds]
this->set_time_offset_s(rx_position_and_time(3));
DLOG(INFO) << "RTKLIB Position at RX TOW = " << gnss_observables_map.begin()->second.RX_time
<< " in ECEF (X,Y,Z,t[meters]) = " << rx_position_and_time;
boost::posix_time::ptime p_time;
// gtime_t rtklib_utc_time = gpst2utc(pvt_sol.time); //Corrected RX Time (Non integer multiply of 1 ms of granularity)
// Uncorrected RX Time (integer multiply of 1 ms and the same observables time reported in RTCM and RINEX)
gtime_t rtklib_time = gpst2time(adjgpsweek(nav_data.eph[0].week), gnss_observables_map.begin()->second.RX_time);
gtime_t rtklib_utc_time = gpst2utc(rtklib_time);
p_time = boost::posix_time::from_time_t(rtklib_utc_time.time);
p_time += boost::posix_time::microseconds(static_cast<long>(round(rtklib_utc_time.sec * 1e6))); // NOLINT(google-runtime-int)
this->set_position_UTC_time(p_time);
cart2geo(static_cast<double>(rx_position_and_time(0)), static_cast<double>(rx_position_and_time(1)), static_cast<double>(rx_position_and_time(2)), 4);
DLOG(INFO) << "RTKLIB Position at " << boost::posix_time::to_simple_string(p_time)
<< " is Lat = " << this->get_latitude() << " [deg], Long = " << this->get_longitude()
<< " [deg], Height= " << this->get_height() << " [m]"
<< " RX time offset= " << this->get_time_offset_s() << " [s]";
// PVT MONITOR
// TOW
monitor_pvt.TOW_at_current_symbol_ms = gnss_observables_map.begin()->second.TOW_at_current_symbol_ms;
// WEEK
monitor_pvt.week = adjgpsweek(nav_data.eph[0].week);
// PVT GPS time
monitor_pvt.RX_time = gnss_observables_map.begin()->second.RX_time;
// User clock offset [s]
monitor_pvt.user_clk_offset = rx_position_and_time(3);
// ECEF POS X,Y,X [m] + ECEF VEL X,Y,X [m/s] (6 x double)
monitor_pvt.pos_x = pvt_sol.rr[0];
monitor_pvt.pos_y = pvt_sol.rr[1];
monitor_pvt.pos_z = pvt_sol.rr[2];
monitor_pvt.vel_x = pvt_sol.rr[3];
monitor_pvt.vel_y = pvt_sol.rr[4];
monitor_pvt.vel_z = pvt_sol.rr[5];
// position variance/covariance (m^2) {c_xx,c_yy,c_zz,c_xy,c_yz,c_zx} (6 x double)
monitor_pvt.cov_xx = pvt_sol.qr[0];
monitor_pvt.cov_yy = pvt_sol.qr[1];
monitor_pvt.cov_zz = pvt_sol.qr[2];
monitor_pvt.cov_xy = pvt_sol.qr[3];
monitor_pvt.cov_yz = pvt_sol.qr[4];
monitor_pvt.cov_zx = pvt_sol.qr[5];
// GEO user position Latitude [deg]
monitor_pvt.latitude = get_latitude();
// GEO user position Longitude [deg]
monitor_pvt.longitude = get_longitude();
// GEO user position Height [m]
monitor_pvt.height = get_height();
// NUMBER OF VALID SATS
monitor_pvt.valid_sats = pvt_sol.ns;
// RTKLIB solution status
monitor_pvt.solution_status = pvt_sol.stat;
// RTKLIB solution type (0:xyz-ecef,1:enu-baseline)
monitor_pvt.solution_type = pvt_sol.type;
// AR ratio factor for validation
monitor_pvt.AR_ratio_factor = pvt_sol.ratio;
// AR ratio threshold for validation
monitor_pvt.AR_ratio_threshold = pvt_sol.thres;
// GDOP / PDOP/ HDOP/ VDOP
monitor_pvt.gdop = dop_[0];
monitor_pvt.pdop = dop_[1];
monitor_pvt.hdop = dop_[2];
monitor_pvt.vdop = dop_[3];
// ######## LOG FILE #########
if (d_flag_dump_enabled == true)
{
// MULTIPLEXED FILE RECORDING - Record results to file
try
{
double tmp_double;
uint32_t tmp_uint32;
// TOW
tmp_uint32 = gnss_observables_map.begin()->second.TOW_at_current_symbol_ms;
d_dump_file.write(reinterpret_cast<char *>(&tmp_uint32), sizeof(uint32_t));
// WEEK
tmp_uint32 = adjgpsweek(nav_data.eph[0].week);
d_dump_file.write(reinterpret_cast<char *>(&tmp_uint32), sizeof(uint32_t));
// PVT GPS time
tmp_double = gnss_observables_map.begin()->second.RX_time;
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// User clock offset [s]
tmp_double = rx_position_and_time(3);
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// ECEF POS X,Y,X [m] + ECEF VEL X,Y,X [m/s] (6 x double)
tmp_double = pvt_sol.rr[0];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.rr[1];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.rr[2];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.rr[3];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.rr[4];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.rr[5];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// position variance/covariance (m^2) {c_xx,c_yy,c_zz,c_xy,c_yz,c_zx} (6 x double)
tmp_double = pvt_sol.qr[0];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.qr[1];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.qr[2];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.qr[3];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.qr[4];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
tmp_double = pvt_sol.qr[5];
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// GEO user position Latitude [deg]
tmp_double = get_latitude();
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// GEO user position Longitude [deg]
tmp_double = get_longitude();
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// GEO user position Height [m]
tmp_double = get_height();
d_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
// NUMBER OF VALID SATS
d_dump_file.write(reinterpret_cast<char *>(&pvt_sol.ns), sizeof(uint8_t));
// RTKLIB solution status
d_dump_file.write(reinterpret_cast<char *>(&pvt_sol.stat), sizeof(uint8_t));
// RTKLIB solution type (0:xyz-ecef,1:enu-baseline)
d_dump_file.write(reinterpret_cast<char *>(&pvt_sol.type), sizeof(uint8_t));
// AR ratio factor for validation
d_dump_file.write(reinterpret_cast<char *>(&pvt_sol.ratio), sizeof(float));
// AR ratio threshold for validation
d_dump_file.write(reinterpret_cast<char *>(&pvt_sol.thres), sizeof(float));
// GDOP / PDOP/ HDOP/ VDOP
d_dump_file.write(reinterpret_cast<char *>(&dop_[0]), sizeof(double));
d_dump_file.write(reinterpret_cast<char *>(&dop_[1]), sizeof(double));
d_dump_file.write(reinterpret_cast<char *>(&dop_[2]), sizeof(double));
d_dump_file.write(reinterpret_cast<char *>(&dop_[3]), sizeof(double));
}
catch (const std::ifstream::failure &e)
{
LOG(WARNING) << "Exception writing RTKLIB dump file " << e.what();
}
}
}
}
return is_valid_position();
}
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