mirror of https://github.com/gnss-sdr/gnss-sdr
187 lines
12 KiB
C++
187 lines
12 KiB
C++
/*!
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* \file gps_cnav_ephemeris.h
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* \brief Interface of a GPS CNAV EPHEMERIS storage
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* \author Javier Arribas, 2015. jarribas(at)cttc.es
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*
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* -------------------------------------------------------------------------
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*
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* Copyright (C) 2010-2019 (see AUTHORS file for a list of contributors)
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*
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* GNSS-SDR is a software defined Global Navigation
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* Satellite Systems receiver
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*
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* This file is part of GNSS-SDR.
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*
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* SPDX-License-Identifier: GPL-3.0-or-later
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*
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* -------------------------------------------------------------------------
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*/
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#ifndef GNSS_SDR_GPS_CNAV_EPHEMERIS_H
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#define GNSS_SDR_GPS_CNAV_EPHEMERIS_H
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#include <boost/serialization/nvp.hpp>
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#include <cstdint>
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/*!
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* \brief This class is a storage and orbital model functions for the GPS SV ephemeris data as described in IS-GPS-200K
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*
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* See https://www.gps.gov/technical/icwg/IS-GPS-200K.pdf Appendix III
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*/
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class Gps_CNAV_Ephemeris
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{
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public:
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/*!
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* Default constructor
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*/
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Gps_CNAV_Ephemeris() = default;
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/*!
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* \brief Compute the ECEF SV coordinates and ECEF velocity
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* Implementation of Table 20-IV (IS-GPS-200K)
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*/
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double satellitePosition(double transmitTime);
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/*!
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* \brief Sets (\a d_satClkDrift)and returns the clock drift in seconds according to the User Algorithm for SV Clock Correction
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* (IS-GPS-200K, 20.3.3.3.3.1)
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*/
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double sv_clock_drift(double transmitTime);
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/*!
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* \brief Sets (\a d_dtr) and returns the clock relativistic correction term in seconds according to the User Algorithm for SV Clock Correction
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* (IS-GPS-200K, 20.3.3.3.3.1)
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*/
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double sv_clock_relativistic_term(double transmitTime);
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uint32_t i_satellite_PRN{}; // SV PRN NUMBER
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// Message Types 10 and 11 Parameters (1 of 2)
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int32_t i_GPS_week{}; //!< GPS week number, aka WN [week]
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int32_t i_URA{}; //!< ED Accuracy Index
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int32_t i_signal_health{}; //!< Signal health (L1/L2/L5)
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int32_t d_Top{}; //!< Data predict time of week
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double d_DELTA_A{}; //!< Semi-major axis difference at reference time
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double d_A_DOT{}; //!< Change rate in semi-major axis
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double d_Delta_n{}; //!< Mean Motion Difference From Computed Value [semi-circles/s]
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double d_DELTA_DOT_N{}; //!< Rate of mean motion difference from computed value
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double d_M_0{}; //!< Mean Anomaly at Reference Time [semi-circles]
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double d_e_eccentricity{}; //!< Eccentricity
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double d_OMEGA{}; //!< Argument of Perigee [semi-cicles]
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double d_OMEGA0{}; //!< Longitude of Ascending Node of Orbit Plane at Weekly Epoch [semi-cicles]
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int32_t d_Toe1{}; //!< Ephemeris data reference time of week (Ref. 20.3.3.4.3 IS-GPS-200K) [s]
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int32_t d_Toe2{}; //!< Ephemeris data reference time of week (Ref. 20.3.3.4.3 IS-GPS-200K) [s]
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double d_DELTA_OMEGA_DOT{}; //!< Rate of Right Ascension difference [semi-circles/s]
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double d_i_0{}; //!< Inclination Angle at Reference Time [semi-circles]
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double d_IDOT{}; //!< Rate of Inclination Angle [semi-circles/s]
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double d_Cis{}; //!< Amplitude of the Sine Harmonic Correction Term to the Angle of Inclination [rad]
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double d_Cic{}; //!< Amplitude of the Cosine Harmonic Correction Term to the Angle of Inclination [rad]
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double d_Crs{}; //!< Amplitude of the Sine Harmonic Correction Term to the Orbit Radius [m]
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double d_Crc{}; //!< Amplitude of the Cosine Harmonic Correction Term to the Orbit Radius [m]
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double d_Cus{}; //!< Amplitude of the Sine Harmonic Correction Term to the Argument of Latitude [rad]
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double d_Cuc{}; //!< Amplitude of the Cosine Harmonic Correction Term to the Argument of Latitude [rad]
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// Clock Correction and Accuracy Parameters
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int32_t d_Toc{}; //!< clock data reference time (Ref. 20.3.3.3.3.1 IS-GPS-200K) [s]
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double d_A_f0{}; //!< Coefficient 0 of code phase offset model [s]
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double d_A_f1{}; //!< Coefficient 1 of code phase offset model [s/s]
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double d_A_f2{}; //!< Coefficient 2 of code phase offset model [s/s^2]
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double d_URA0{}; //!< NED Accuracy Index
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double d_URA1{}; //!< NED Accuracy Change Index
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double d_URA2{}; //!< NED Accuracy Change Rate Index
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// Group Delay Differential Parameters
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double d_TGD{}; //!< Estimated Group Delay Differential: L1-L2 correction term only for the benefit of "L1 P(Y)" or "L2 P(Y)" s users [s]
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double d_ISCL1{};
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double d_ISCL2{};
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double d_ISCL5I{};
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double d_ISCL5Q{};
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int32_t d_TOW{}; //!< Time of GPS Week of the ephemeris set (taken from subframes TOW) [s]
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// clock terms derived from ephemeris data
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double d_satClkDrift{}; //!< GPS clock error
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double d_dtr{}; //!< relativistic clock correction term
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// satellite positions
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double d_satpos_X{}; //!< Earth-fixed coordinate x of the satellite [m]. Intersection of the IERS Reference Meridian (IRM) and the plane passing through the origin and normal to the Z-axis.
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double d_satpos_Y{}; //!< Earth-fixed coordinate y of the satellite [m]. Completes a right-handed, Earth-Centered, Earth-Fixed orthogonal coordinate system.
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double d_satpos_Z{}; //!< Earth-fixed coordinate z of the satellite [m]. The direction of the IERS (International Earth Rotation and Reference Systems Service) Reference Pole (IRP).
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// Satellite velocity
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double d_satvel_X{}; //!< Earth-fixed velocity coordinate x of the satellite [m]
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double d_satvel_Y{}; //!< Earth-fixed velocity coordinate y of the satellite [m]
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double d_satvel_Z{}; //!< Earth-fixed velocity coordinate z of the satellite [m]
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/*! \brief If true, enhanced level of integrity assurance.
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*
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* If false, indicates that the conveying signal is provided with the legacy level of integrity assurance.
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* That is, the probability that the instantaneous URE of the conveying signal exceeds 4.42 times the upper bound
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* value of the current broadcast URA index, for more than 5.2 seconds, without an accompanying alert, is less
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* than 1E-5 per hour. If true, indicates that the conveying signal is provided with an enhanced level of
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* integrity assurance. That is, the probability that the instantaneous URE of the conveying signal exceeds 5.73
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* times the upper bound value of the current broadcast URA index, for more than 5.2 seconds, without an
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* accompanying alert, is less than 1E-8 per hour.
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*/
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bool b_integrity_status_flag{};
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bool b_l2c_phasing_flag{};
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bool b_alert_flag{}; //!< If true, indicates that the SV URA may be worse than indicated in d_SV_accuracy, use that SV at our own risk.
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bool b_antispoofing_flag{}; //!< If true, the AntiSpoofing mode is ON in that SV
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template <class Archive>
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/*!
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* \brief Serialize is a boost standard method to be called by the boost XML serialization. Here is used to save the ephemeris data on disk file.
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*/
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inline void serialize(Archive& archive, const uint32_t version)
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{
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using boost::serialization::make_nvp;
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if (version)
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{
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};
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archive& make_nvp("i_satellite_PRN", i_satellite_PRN); // SV PRN NUMBER
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archive& make_nvp("d_TOW", d_TOW); //!< Time of GPS Week of the ephemeris set (taken from subframes TOW) [s]
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archive& make_nvp("d_Crs", d_Crs); //!< Amplitude of the Sine Harmonic Correction Term to the Orbit Radius [m]
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archive& make_nvp("d_M_0", d_M_0); //!< Mean Anomaly at Reference Time [semi-circles]
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archive& make_nvp("d_Cuc", d_Cuc); //!< Amplitude of the Cosine Harmonic Correction Term to the Argument of Latitude [rad]
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archive& make_nvp("d_e_eccentricity", d_e_eccentricity); //!< Eccentricity [dimensionless]
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archive& make_nvp("d_Cus", d_Cus); //!< Amplitude of the Sine Harmonic Correction Term to the Argument of Latitude [rad]
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archive& make_nvp("d_Toe1", d_Toe1); //!< Ephemeris data reference time of week (Ref. 20.3.3.4.3 IS-GPS-200K) [s]
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archive& make_nvp("d_Toe2", d_Toe2); //!< Ephemeris data reference time of week (Ref. 20.3.3.4.3 IS-GPS-200K) [s]
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archive& make_nvp("d_Toc", d_Toc); //!< clock data reference time (Ref. 20.3.3.3.3.1 IS-GPS-200K) [s]
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archive& make_nvp("d_Cic", d_Cic); //!< Amplitude of the Cosine Harmonic Correction Term to the Angle of Inclination [rad]
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archive& make_nvp("d_OMEGA0", d_OMEGA0); //!< Longitude of Ascending Node of Orbit Plane at Weekly Epoch [semi-circles]
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archive& make_nvp("d_Cis", d_Cis); //!< Amplitude of the Sine Harmonic Correction Term to the Angle of Inclination [rad]
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archive& make_nvp("d_i_0", d_i_0); //!< Inclination Angle at Reference Time [semi-circles]
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archive& make_nvp("d_Crc", d_Crc); //!< Amplitude of the Cosine Harmonic Correction Term to the Orbit Radius [m]
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archive& make_nvp("d_OMEGA", d_OMEGA); //!< Argument of Perigee [semi-cicles]
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archive& make_nvp("d_IDOT", d_IDOT); //!< Rate of Inclination Angle [semi-circles/s]
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archive& make_nvp("i_GPS_week", i_GPS_week); //!< GPS week number, aka WN [week]
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archive& make_nvp("d_TGD", d_TGD); //!< Estimated Group Delay Differential: L1-L2 correction term only for the benefit of "L1 P(Y)" or "L2 P(Y)" s users [s]
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archive& make_nvp("d_ISCL1", d_ISCL1); //!< Estimated Group Delay Differential: L1P(Y)-L1C/A correction term only for the benefit of "L1 P(Y)" or "L2 P(Y)" s users [s]
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archive& make_nvp("d_ISCL2", d_ISCL2); //!< Estimated Group Delay Differential: L1P(Y)-L2C correction term only for the benefit of "L1 P(Y)" or "L2 P(Y)" s users [s]
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archive& make_nvp("d_ISCL5I", d_ISCL5I); //!< Estimated Group Delay Differential: L1P(Y)-L5i correction term only for the benefit of "L1 P(Y)" or "L2 P(Y)" s users [s]
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archive& make_nvp("d_ISCL5Q", d_ISCL5Q); //!< Estimated Group Delay Differential: L1P(Y)-L5q correction term only for the benefit of "L1 P(Y)" or "L2 P(Y)" s users [s]
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archive& make_nvp("d_DELTA_A", d_DELTA_A); //!< Semi-major axis difference at reference time [m]
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archive& make_nvp("d_A_DOT", d_A_DOT); //!< Change rate in semi-major axis [m/s]
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archive& make_nvp("d_DELTA_OMEGA_DOT", d_DELTA_OMEGA_DOT); //!< Rate of Right Ascension difference [semi-circles/s]
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archive& make_nvp("d_A_f0", d_A_f0); //!< Coefficient 0 of code phase offset model [s]
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archive& make_nvp("d_A_f1", d_A_f1); //!< Coefficient 1 of code phase offset model [s/s]
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archive& make_nvp("d_A_f2", d_A_f2); //!< Coefficient 2 of code phase offset model [s/s^2]
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archive& make_nvp("b_integrity_status_flag", b_integrity_status_flag);
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archive& make_nvp("b_alert_flag", b_alert_flag); //!< If true, indicates that the SV URA may be worse than indicated in d_SV_accuracy, use that SV at our own risk.
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archive& make_nvp("b_antispoofing_flag", b_antispoofing_flag); //!< If true, the AntiSpoofing mode is ON in that SV
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}
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private:
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double check_t(double time);
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};
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#endif
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