#include #include #include #include #include #include "ephemeris.h" #include "bncutils.h" #include "bnctime.h" #include "bnccore.h" #include "bncutils.h" #include "satObs.h" #include "pppInclude.h" #include "pppModel.h" using namespace std; // Constructor //////////////////////////////////////////////////////////////////////////// t_eph::t_eph() { _checkState = unchecked; _orbCorr = 0; _clkCorr = 0; } // //////////////////////////////////////////////////////////////////////////// void t_eph::setOrbCorr(const t_orbCorr* orbCorr) { delete _orbCorr; _orbCorr = new t_orbCorr(*orbCorr); } // //////////////////////////////////////////////////////////////////////////// void t_eph::setClkCorr(const t_clkCorr* clkCorr) { delete _clkCorr; _clkCorr = new t_clkCorr(*clkCorr); } // //////////////////////////////////////////////////////////////////////////// t_irc t_eph::getCrd(const bncTime& tt, ColumnVector& xc, ColumnVector& vv, bool useCorr) const { if (_checkState == bad) { return failure; } const QVector updateInt = QVector() << 1 << 2 << 5 << 10 << 15 << 30 << 60 << 120 << 240 << 300 << 600 << 900 << 1800 << 3600 << 7200 << 10800; xc.ReSize(4); vv.ReSize(3); if (position(tt.gpsw(), tt.gpssec(), xc.data(), vv.data()) != success) { return failure; } if (useCorr) { if (_orbCorr && _clkCorr) { double dtO = tt - _orbCorr->_time; if (_orbCorr->_updateInt) { dtO -= (0.5 * updateInt[_orbCorr->_updateInt]); } ColumnVector dx(3); dx[0] = _orbCorr->_xr[0] + _orbCorr->_dotXr[0] * dtO; dx[1] = _orbCorr->_xr[1] + _orbCorr->_dotXr[1] * dtO; dx[2] = _orbCorr->_xr[2] + _orbCorr->_dotXr[2] * dtO; if (_orbCorr->_system == 'R') { RSW_to_XYZ(xc.Rows(1,3), vv.Rows(1,3), dx, dx); } xc[0] -= dx[0]; xc[1] -= dx[1]; xc[2] -= dx[2]; double dtC = tt - _clkCorr->_time; if (_clkCorr->_updateInt) { dtC -= (0.5 * updateInt[_clkCorr->_updateInt]); } xc[3] += _clkCorr->_dClk + _clkCorr->_dotDClk * dtC + _clkCorr->_dotDotDClk * dtC * dtC; } else { return failure; } } return success; } // Set GPS Satellite Position //////////////////////////////////////////////////////////////////////////// void t_ephGPS::set(const gpsephemeris* ee) { _receptDateTime = currentDateAndTimeGPS(); if (PRN_GPS_START <= ee->satellite && ee->satellite <= PRN_GPS_END) { _prn.set('G', ee->satellite); } else if (PRN_QZSS_START <= ee->satellite && ee->satellite <= PRN_QZSS_END) { _prn.set('J', ee->satellite - PRN_QZSS_START + 1); } else { _checkState = bad; return; } _TOC.set(ee->GPSweek, ee->TOC); _clock_bias = ee->clock_bias; _clock_drift = ee->clock_drift; _clock_driftrate = ee->clock_driftrate; _IODE = ee->IODE; _Crs = ee->Crs; _Delta_n = ee->Delta_n; _M0 = ee->M0; _Cuc = ee->Cuc; _e = ee->e; _Cus = ee->Cus; _sqrt_A = ee->sqrt_A; _TOEsec = ee->TOE; _Cic = ee->Cic; _OMEGA0 = ee->OMEGA0; _Cis = ee->Cis; _i0 = ee->i0; _Crc = ee->Crc; _omega = ee->omega; _OMEGADOT = ee->OMEGADOT; _IDOT = ee->IDOT; _L2Codes = 0.0; _TOEweek = ee->GPSweek; _L2PFlag = 0.0; if (ee->URAindex <= 6) { _ura = ceil(10.0*pow(2.0, 1.0+((double)ee->URAindex)/2.0))/10.0; } else { _ura = ceil(10.0*pow(2.0, ((double)ee->URAindex)/2.0))/10.0; } _health = ee->SVhealth; _TGD = ee->TGD; _IODC = ee->IODC; _TOT = 0.9999e9; _fitInterval = 0.0; } // Compute GPS Satellite Position (virtual) //////////////////////////////////////////////////////////////////////////// t_irc t_ephGPS::position(int GPSweek, double GPSweeks, double* xc, double* vv) const { if (_checkState == bad) { return failure; } static const double omegaEarth = 7292115.1467e-11; static const double gmGRS = 398.6005e12; memset(xc, 0, 4*sizeof(double)); memset(vv, 0, 3*sizeof(double)); double a0 = _sqrt_A * _sqrt_A; if (a0 == 0) { return failure; } double n0 = sqrt(gmGRS/(a0*a0*a0)); bncTime tt(GPSweek, GPSweeks); double tk = tt - bncTime(int(_TOEweek), _TOEsec); double n = n0 + _Delta_n; double M = _M0 + n*tk; double E = M; double E_last; do { E_last = E; E = M + _e*sin(E); } while ( fabs(E-E_last)*a0 > 0.001 ); double v = 2.0*atan( sqrt( (1.0 + _e)/(1.0 - _e) )*tan( E/2 ) ); double u0 = v + _omega; double sin2u0 = sin(2*u0); double cos2u0 = cos(2*u0); double r = a0*(1 - _e*cos(E)) + _Crc*cos2u0 + _Crs*sin2u0; double i = _i0 + _IDOT*tk + _Cic*cos2u0 + _Cis*sin2u0; double u = u0 + _Cuc*cos2u0 + _Cus*sin2u0; double xp = r*cos(u); double yp = r*sin(u); double OM = _OMEGA0 + (_OMEGADOT - omegaEarth)*tk - omegaEarth*_TOEsec; double sinom = sin(OM); double cosom = cos(OM); double sini = sin(i); double cosi = cos(i); xc[0] = xp*cosom - yp*cosi*sinom; xc[1] = xp*sinom + yp*cosi*cosom; xc[2] = yp*sini; double tc = tt - _TOC; xc[3] = _clock_bias + _clock_drift*tc + _clock_driftrate*tc*tc; // Velocity // -------- double tanv2 = tan(v/2); double dEdM = 1 / (1 - _e*cos(E)); double dotv = sqrt((1.0 + _e)/(1.0 - _e)) / cos(E/2)/cos(E/2) / (1 + tanv2*tanv2) * dEdM * n; double dotu = dotv + (-_Cuc*sin2u0 + _Cus*cos2u0)*2*dotv; double dotom = _OMEGADOT - omegaEarth; double doti = _IDOT + (-_Cic*sin2u0 + _Cis*cos2u0)*2*dotv; double dotr = a0 * _e*sin(E) * dEdM * n + (-_Crc*sin2u0 + _Crs*cos2u0)*2*dotv; double dotx = dotr*cos(u) - r*sin(u)*dotu; double doty = dotr*sin(u) + r*cos(u)*dotu; vv[0] = cosom *dotx - cosi*sinom *doty // dX / dr - xp*sinom*dotom - yp*cosi*cosom*dotom // dX / dOMEGA + yp*sini*sinom*doti; // dX / di vv[1] = sinom *dotx + cosi*cosom *doty + xp*cosom*dotom - yp*cosi*sinom*dotom - yp*sini*cosom*doti; vv[2] = sini *doty + yp*cosi *doti; // Relativistic Correction // ----------------------- xc[3] -= 2.0 * (xc[0]*vv[0] + xc[1]*vv[1] + xc[2]*vv[2]) / t_CST::c / t_CST::c; return success; } // Derivative of the state vector using a simple force model (static) //////////////////////////////////////////////////////////////////////////// ColumnVector t_ephGlo::glo_deriv(double /* tt */, const ColumnVector& xv, double* acc) { // State vector components // ----------------------- ColumnVector rr = xv.rows(1,3); ColumnVector vv = xv.rows(4,6); // Acceleration // ------------ static const double gmWGS = 398.60044e12; static const double AE = 6378136.0; static const double OMEGA = 7292115.e-11; static const double C20 = -1082.6257e-6; double rho = rr.norm_Frobenius(); double t1 = -gmWGS/(rho*rho*rho); double t2 = 3.0/2.0 * C20 * (gmWGS*AE*AE) / (rho*rho*rho*rho*rho); double t3 = OMEGA * OMEGA; double t4 = 2.0 * OMEGA; double z2 = rr(3) * rr(3); // Vector of derivatives // --------------------- ColumnVector va(6); va(1) = vv(1); va(2) = vv(2); va(3) = vv(3); va(4) = (t1 + t2*(1.0-5.0*z2/(rho*rho)) + t3) * rr(1) + t4*vv(2) + acc[0]; va(5) = (t1 + t2*(1.0-5.0*z2/(rho*rho)) + t3) * rr(2) - t4*vv(1) + acc[1]; va(6) = (t1 + t2*(3.0-5.0*z2/(rho*rho)) ) * rr(3) + acc[2]; return va; } // Compute Glonass Satellite Position (virtual) //////////////////////////////////////////////////////////////////////////// t_irc t_ephGlo::position(int GPSweek, double GPSweeks, double* xc, double* vv) const { if (_checkState == bad) { return failure; } static const double nominalStep = 10.0; memset(xc, 0, 4*sizeof(double)); memset(vv, 0, 3*sizeof(double)); double dtPos = bncTime(GPSweek, GPSweeks) - _tt; if (fabs(dtPos) > 24*3600.0) { return failure; } int nSteps = int(fabs(dtPos) / nominalStep) + 1; double step = dtPos / nSteps; double acc[3]; acc[0] = _x_acceleration * 1.e3; acc[1] = _y_acceleration * 1.e3; acc[2] = _z_acceleration * 1.e3; for (int ii = 1; ii <= nSteps; ii++) { _xv = rungeKutta4(_tt.gpssec(), _xv, step, acc, glo_deriv); _tt = _tt + step; } // Position and Velocity // --------------------- xc[0] = _xv(1); xc[1] = _xv(2); xc[2] = _xv(3); vv[0] = _xv(4); vv[1] = _xv(5); vv[2] = _xv(6); // Clock Correction // ---------------- double dtClk = bncTime(GPSweek, GPSweeks) - _TOC; xc[3] = -_tau + _gamma * dtClk; return success; } // IOD of Glonass Ephemeris (virtual) //////////////////////////////////////////////////////////////////////////// int t_ephGlo::IOD() const { bncTime tMoscow = _TOC - _gps_utc + 3 * 3600.0; return int(tMoscow.daysec() / 900); } // Set Glonass Ephemeris //////////////////////////////////////////////////////////////////////////// void t_ephGlo::set(const glonassephemeris* ee) { _receptDateTime = currentDateAndTimeGPS(); _prn.set('R', ee->almanac_number); int ww = ee->GPSWeek; int tow = ee->GPSTOW; updatetime(&ww, &tow, ee->tb*1000, 0); // Moscow -> GPS // Check the day once more // ----------------------- bool timeChanged = false; { const double secPerDay = 24 * 3600.0; const double secPerWeek = 7 * secPerDay; int ww_old = ww; int tow_old = tow; int currentWeek; double currentSec; currentGPSWeeks(currentWeek, currentSec); bncTime currentTime(currentWeek, currentSec); bncTime hTime(ww, (double) tow); if (hTime - currentTime > secPerDay/2.0) { timeChanged = true; tow -= int(secPerDay); if (tow < 0) { tow += int(secPerWeek); ww -= 1; } } else if (hTime - currentTime < -secPerDay/2.0) { timeChanged = true; tow += int(secPerDay); if (tow > secPerWeek) { tow -= int(secPerWeek); ww += 1; } } if (false && timeChanged && BNC_CORE->mode() == t_bncCore::batchPostProcessing) { bncTime newHTime(ww, (double) tow); cout << "GLONASS " << ee->almanac_number << " Time Changed at " << currentTime.datestr() << " " << currentTime.timestr() << endl << "old: " << hTime.datestr() << " " << hTime.timestr() << endl << "new: " << newHTime.datestr() << " " << newHTime.timestr() << endl << "eph: " << ee->GPSWeek << " " << ee->GPSTOW << " " << ee->tb << endl << "ww, tow (old): " << ww_old << " " << tow_old << endl << "ww, tow (new): " << ww << " " << tow << endl << endl; } } bncTime hlpTime(ww, (double) tow); unsigned year, month, day; hlpTime.civil_date(year, month, day); _gps_utc = gnumleap(year, month, day); _TOC.set(ww, tow); _E = ee->E; _tau = ee->tau; _gamma = ee->gamma; _x_pos = ee->x_pos; _x_velocity = ee->x_velocity; _x_acceleration = ee->x_acceleration; _y_pos = ee->y_pos; _y_velocity = ee->y_velocity; _y_acceleration = ee->y_acceleration; _z_pos = ee->z_pos; _z_velocity = ee->z_velocity; _z_acceleration = ee->z_acceleration; _health = 0; _frequency_number = ee->frequency_number; _tki = ee->tk-3*60*60; if (_tki < 0) _tki += 86400; // Initialize status vector // ------------------------ _tt = _TOC; _xv(1) = _x_pos * 1.e3; _xv(2) = _y_pos * 1.e3; _xv(3) = _z_pos * 1.e3; _xv(4) = _x_velocity * 1.e3; _xv(5) = _y_velocity * 1.e3; _xv(6) = _z_velocity * 1.e3; } // Set Galileo Satellite Position //////////////////////////////////////////////////////////////////////////// void t_ephGal::set(const galileoephemeris* ee) { _receptDateTime = currentDateAndTimeGPS(); _prn.set('E', ee->satellite); _TOC.set(ee->Week, ee->TOC); _clock_bias = ee->clock_bias; _clock_drift = ee->clock_drift; _clock_driftrate = ee->clock_driftrate; _IODnav = ee->IODnav; _Crs = ee->Crs; _Delta_n = ee->Delta_n; _M0 = ee->M0; _Cuc = ee->Cuc; _e = ee->e; _Cus = ee->Cus; _sqrt_A = ee->sqrt_A; _TOEsec = _TOC.gpssec(); //// _TOEsec = ee->TOE; //// TODO: _Cic = ee->Cic; _OMEGA0 = ee->OMEGA0; _Cis = ee->Cis; _i0 = ee->i0; _Crc = ee->Crc; _omega = ee->omega; _OMEGADOT = ee->OMEGADOT; _IDOT = ee->IDOT; _TOEweek = ee->Week; _SISA = ee->SISA; _E5aHS = ee->E5aHS; _E5bHS = ee->E5bHS; _BGD_1_5A = ee->BGD_1_5A; _BGD_1_5B = ee->BGD_1_5B; _TOT = 0.9999e9; _flags = ee->flags; } // Compute Galileo Satellite Position (virtual) //////////////////////////////////////////////////////////////////////////// t_irc t_ephGal::position(int GPSweek, double GPSweeks, double* xc, double* vv) const { if (_checkState == bad) { return failure; } static const double omegaEarth = 7292115.1467e-11; static const double gmWGS = 398.60044e12; memset(xc, 0, 4*sizeof(double)); memset(vv, 0, 3*sizeof(double)); double a0 = _sqrt_A * _sqrt_A; if (a0 == 0) { return failure; } double n0 = sqrt(gmWGS/(a0*a0*a0)); bncTime tt(GPSweek, GPSweeks); double tk = tt - bncTime(_TOC.gpsw(), _TOEsec); double n = n0 + _Delta_n; double M = _M0 + n*tk; double E = M; double E_last; do { E_last = E; E = M + _e*sin(E); } while ( fabs(E-E_last)*a0 > 0.001 ); double v = 2.0*atan( sqrt( (1.0 + _e)/(1.0 - _e) )*tan( E/2 ) ); double u0 = v + _omega; double sin2u0 = sin(2*u0); double cos2u0 = cos(2*u0); double r = a0*(1 - _e*cos(E)) + _Crc*cos2u0 + _Crs*sin2u0; double i = _i0 + _IDOT*tk + _Cic*cos2u0 + _Cis*sin2u0; double u = u0 + _Cuc*cos2u0 + _Cus*sin2u0; double xp = r*cos(u); double yp = r*sin(u); double OM = _OMEGA0 + (_OMEGADOT - omegaEarth)*tk - omegaEarth*_TOEsec; double sinom = sin(OM); double cosom = cos(OM); double sini = sin(i); double cosi = cos(i); xc[0] = xp*cosom - yp*cosi*sinom; xc[1] = xp*sinom + yp*cosi*cosom; xc[2] = yp*sini; double tc = tt - _TOC; xc[3] = _clock_bias + _clock_drift*tc + _clock_driftrate*tc*tc; // Velocity // -------- double tanv2 = tan(v/2); double dEdM = 1 / (1 - _e*cos(E)); double dotv = sqrt((1.0 + _e)/(1.0 - _e)) / cos(E/2)/cos(E/2) / (1 + tanv2*tanv2) * dEdM * n; double dotu = dotv + (-_Cuc*sin2u0 + _Cus*cos2u0)*2*dotv; double dotom = _OMEGADOT - omegaEarth; double doti = _IDOT + (-_Cic*sin2u0 + _Cis*cos2u0)*2*dotv; double dotr = a0 * _e*sin(E) * dEdM * n + (-_Crc*sin2u0 + _Crs*cos2u0)*2*dotv; double dotx = dotr*cos(u) - r*sin(u)*dotu; double doty = dotr*sin(u) + r*cos(u)*dotu; vv[0] = cosom *dotx - cosi*sinom *doty // dX / dr - xp*sinom*dotom - yp*cosi*cosom*dotom // dX / dOMEGA + yp*sini*sinom*doti; // dX / di vv[1] = sinom *dotx + cosi*cosom *doty + xp*cosom*dotom - yp*cosi*sinom*dotom - yp*sini*cosom*doti; vv[2] = sini *doty + yp*cosi *doti; // Relativistic Correction // ----------------------- // xc(4) -= 4.442807633e-10 * _e * sqrt(a0) *sin(E); xc[3] -= 2.0 * (xc[0]*vv[0] + xc[1]*vv[1] + xc[2]*vv[2]) / t_CST::c / t_CST::c; return success; } // Constructor ////////////////////////////////////////////////////////////////////////////// t_ephGPS::t_ephGPS(float rnxVersion, const QStringList& lines) { const int nLines = 8; if (lines.size() != nLines) { _checkState = bad; return; } // RINEX Format // ------------ int fieldLen = 19; int pos[4]; pos[0] = (rnxVersion <= 2.12) ? 3 : 4; pos[1] = pos[0] + fieldLen; pos[2] = pos[1] + fieldLen; pos[3] = pos[2] + fieldLen; // Read eight lines // ---------------- for (int iLine = 0; iLine < nLines; iLine++) { QString line = lines[iLine]; if ( iLine == 0 ) { QTextStream in(line.left(pos[1]).toAscii()); int year, month, day, hour, min; double sec; QString prnStr; in >> prnStr >> year >> month >> day >> hour >> min >> sec; if (prnStr.at(0) == 'G') { _prn.set('G', prnStr.mid(1).toInt()); } else if (prnStr.at(0) == 'J') { _prn.set('J', prnStr.mid(1).toInt()); } else { _prn.set('G', prnStr.toInt()); } if (year < 80) { year += 2000; } else if (year < 100) { year += 1900; } _TOC.set(year, month, day, hour, min, sec); if ( readDbl(line, pos[1], fieldLen, _clock_bias ) || readDbl(line, pos[2], fieldLen, _clock_drift ) || readDbl(line, pos[3], fieldLen, _clock_driftrate) ) { _checkState = bad; return; } } else if ( iLine == 1 ) { if ( readDbl(line, pos[0], fieldLen, _IODE ) || readDbl(line, pos[1], fieldLen, _Crs ) || readDbl(line, pos[2], fieldLen, _Delta_n) || readDbl(line, pos[3], fieldLen, _M0 ) ) { _checkState = bad; return; } } else if ( iLine == 2 ) { if ( readDbl(line, pos[0], fieldLen, _Cuc ) || readDbl(line, pos[1], fieldLen, _e ) || readDbl(line, pos[2], fieldLen, _Cus ) || readDbl(line, pos[3], fieldLen, _sqrt_A) ) { _checkState = bad; return; } } else if ( iLine == 3 ) { if ( readDbl(line, pos[0], fieldLen, _TOEsec) || readDbl(line, pos[1], fieldLen, _Cic ) || readDbl(line, pos[2], fieldLen, _OMEGA0) || readDbl(line, pos[3], fieldLen, _Cis ) ) { _checkState = bad; return; } } else if ( iLine == 4 ) { if ( readDbl(line, pos[0], fieldLen, _i0 ) || readDbl(line, pos[1], fieldLen, _Crc ) || readDbl(line, pos[2], fieldLen, _omega ) || readDbl(line, pos[3], fieldLen, _OMEGADOT) ) { _checkState = bad; return; } } else if ( iLine == 5 ) { if ( readDbl(line, pos[0], fieldLen, _IDOT ) || readDbl(line, pos[1], fieldLen, _L2Codes) || readDbl(line, pos[2], fieldLen, _TOEweek ) || readDbl(line, pos[3], fieldLen, _L2PFlag) ) { _checkState = bad; return; } } else if ( iLine == 6 ) { if ( readDbl(line, pos[0], fieldLen, _ura ) || readDbl(line, pos[1], fieldLen, _health) || readDbl(line, pos[2], fieldLen, _TGD ) || readDbl(line, pos[3], fieldLen, _IODC ) ) { _checkState = bad; return; } } else if ( iLine == 7 ) { if ( readDbl(line, pos[0], fieldLen, _TOT) ) { _checkState = bad; return; } readDbl(line, pos[1], fieldLen, _fitInterval); // _fitInterval optional } } } // Constructor ////////////////////////////////////////////////////////////////////////////// t_ephGlo::t_ephGlo(float rnxVersion, const QStringList& lines) { const int nLines = 4; if (lines.size() != nLines) { _checkState = bad; return; } // RINEX Format // ------------ int fieldLen = 19; int pos[4]; pos[0] = (rnxVersion <= 2.12) ? 3 : 4; pos[1] = pos[0] + fieldLen; pos[2] = pos[1] + fieldLen; pos[3] = pos[2] + fieldLen; // Read four lines // --------------- for (int iLine = 0; iLine < nLines; iLine++) { QString line = lines[iLine]; if ( iLine == 0 ) { QTextStream in(line.left(pos[1]).toAscii()); int year, month, day, hour, min; double sec; QString prnStr; in >> prnStr >> year >> month >> day >> hour >> min >> sec; if (prnStr.at(0) == 'R') { _prn.set('R', prnStr.mid(1).toInt()); } else { _prn.set('R', prnStr.toInt()); } if (year < 80) { year += 2000; } else if (year < 100) { year += 1900; } _gps_utc = gnumleap(year, month, day); _TOC.set(year, month, day, hour, min, sec); _TOC = _TOC + _gps_utc; if ( readDbl(line, pos[1], fieldLen, _tau ) || readDbl(line, pos[2], fieldLen, _gamma) || readDbl(line, pos[3], fieldLen, _tki ) ) { _checkState = bad; return; } _tau = -_tau; } else if ( iLine == 1 ) { if ( readDbl(line, pos[0], fieldLen, _x_pos ) || readDbl(line, pos[1], fieldLen, _x_velocity ) || readDbl(line, pos[2], fieldLen, _x_acceleration) || readDbl(line, pos[3], fieldLen, _health ) ) { _checkState = bad; return; } } else if ( iLine == 2 ) { if ( readDbl(line, pos[0], fieldLen, _y_pos ) || readDbl(line, pos[1], fieldLen, _y_velocity ) || readDbl(line, pos[2], fieldLen, _y_acceleration ) || readDbl(line, pos[3], fieldLen, _frequency_number) ) { _checkState = bad; return; } } else if ( iLine == 3 ) { if ( readDbl(line, pos[0], fieldLen, _z_pos ) || readDbl(line, pos[1], fieldLen, _z_velocity ) || readDbl(line, pos[2], fieldLen, _z_acceleration) || readDbl(line, pos[3], fieldLen, _E ) ) { _checkState = bad; return; } } } // Initialize status vector // ------------------------ _tt = _TOC; _xv.ReSize(6); _xv(1) = _x_pos * 1.e3; _xv(2) = _y_pos * 1.e3; _xv(3) = _z_pos * 1.e3; _xv(4) = _x_velocity * 1.e3; _xv(5) = _y_velocity * 1.e3; _xv(6) = _z_velocity * 1.e3; } // Constructor ////////////////////////////////////////////////////////////////////////////// t_ephGal::t_ephGal(float rnxVersion, const QStringList& lines) { const int nLines = 8; if (lines.size() != nLines) { _checkState = bad; return; } // RINEX Format // ------------ int fieldLen = 19; int pos[4]; pos[0] = (rnxVersion <= 2.12) ? 3 : 4; pos[1] = pos[0] + fieldLen; pos[2] = pos[1] + fieldLen; pos[3] = pos[2] + fieldLen; // Read eight lines // ---------------- for (int iLine = 0; iLine < nLines; iLine++) { QString line = lines[iLine]; if ( iLine == 0 ) { QTextStream in(line.left(pos[1]).toAscii()); int year, month, day, hour, min; double sec; QString prnStr; in >> prnStr >> year >> month >> day >> hour >> min >> sec; if (prnStr.at(0) == 'E') { _prn.set('E', prnStr.mid(1).toInt()); } else { _prn.set('E', prnStr.toInt()); } if (year < 80) { year += 2000; } else if (year < 100) { year += 1900; } _TOC.set(year, month, day, hour, min, sec); if ( readDbl(line, pos[1], fieldLen, _clock_bias ) || readDbl(line, pos[2], fieldLen, _clock_drift ) || readDbl(line, pos[3], fieldLen, _clock_driftrate) ) { _checkState = bad; return; } } else if ( iLine == 1 ) { if ( readDbl(line, pos[0], fieldLen, _IODnav ) || readDbl(line, pos[1], fieldLen, _Crs ) || readDbl(line, pos[2], fieldLen, _Delta_n) || readDbl(line, pos[3], fieldLen, _M0 ) ) { _checkState = bad; return; } } else if ( iLine == 2 ) { if ( readDbl(line, pos[0], fieldLen, _Cuc ) || readDbl(line, pos[1], fieldLen, _e ) || readDbl(line, pos[2], fieldLen, _Cus ) || readDbl(line, pos[3], fieldLen, _sqrt_A) ) { _checkState = bad; return; } } else if ( iLine == 3 ) { if ( readDbl(line, pos[0], fieldLen, _TOEsec) || readDbl(line, pos[1], fieldLen, _Cic ) || readDbl(line, pos[2], fieldLen, _OMEGA0) || readDbl(line, pos[3], fieldLen, _Cis ) ) { _checkState = bad; return; } } else if ( iLine == 4 ) { if ( readDbl(line, pos[0], fieldLen, _i0 ) || readDbl(line, pos[1], fieldLen, _Crc ) || readDbl(line, pos[2], fieldLen, _omega ) || readDbl(line, pos[3], fieldLen, _OMEGADOT) ) { _checkState = bad; return; } } else if ( iLine == 5 ) { if ( readDbl(line, pos[0], fieldLen, _IDOT ) || readDbl(line, pos[2], fieldLen, _TOEweek) ) { _checkState = bad; return; } } else if ( iLine == 6 ) { if ( readDbl(line, pos[0], fieldLen, _SISA ) || readDbl(line, pos[1], fieldLen, _E5aHS ) || readDbl(line, pos[2], fieldLen, _BGD_1_5A) || readDbl(line, pos[3], fieldLen, _BGD_1_5B) ) { _checkState = bad; return; } } else if ( iLine == 7 ) { if ( readDbl(line, pos[0], fieldLen, _TOT) ) { _checkState = bad; return; } } } } // ////////////////////////////////////////////////////////////////////////////// QString t_eph::rinexDateStr(const bncTime& tt, const t_prn& prn, double version) { QString prnStr(prn.toString().c_str()); return rinexDateStr(tt, prnStr, version); } // ////////////////////////////////////////////////////////////////////////////// QString t_eph::rinexDateStr(const bncTime& tt, const QString& prnStr, double version) { QString datStr; unsigned year, month, day, hour, min; double sec; tt.civil_date(year, month, day); tt.civil_time(hour, min, sec); QTextStream out(&datStr); if (version < 3.0) { QString prnHlp = prnStr.mid(1,2); if (prnHlp[0] == '0') prnHlp[0] = ' '; out << prnHlp << QString(" %1 %2 %3 %4 %5%6") .arg(year % 100, 2, 10, QChar('0')) .arg(month, 2) .arg(day, 2) .arg(hour, 2) .arg(min, 2) .arg(sec, 5, 'f',1); } else { out << prnStr << QString(" %1 %2 %3 %4 %5 %6") .arg(year, 4) .arg(month, 2, 10, QChar('0')) .arg(day, 2, 10, QChar('0')) .arg(hour, 2, 10, QChar('0')) .arg(min, 2, 10, QChar('0')) .arg(int(sec), 2, 10, QChar('0')); } return datStr; } // RINEX Format String ////////////////////////////////////////////////////////////////////////////// QString t_ephGPS::toString(double version) const { QString rnxStr = rinexDateStr(_TOC, _prn, version); QTextStream out(&rnxStr); out << QString("%1%2%3\n") .arg(_clock_bias, 19, 'e', 12) .arg(_clock_drift, 19, 'e', 12) .arg(_clock_driftrate, 19, 'e', 12); QString fmt = version < 3.0 ? " %1%2%3%4\n" : " %1%2%3%4\n"; out << QString(fmt) .arg(_IODE, 19, 'e', 12) .arg(_Crs, 19, 'e', 12) .arg(_Delta_n, 19, 'e', 12) .arg(_M0, 19, 'e', 12); out << QString(fmt) .arg(_Cuc, 19, 'e', 12) .arg(_e, 19, 'e', 12) .arg(_Cus, 19, 'e', 12) .arg(_sqrt_A, 19, 'e', 12); out << QString(fmt) .arg(_TOEsec, 19, 'e', 12) .arg(_Cic, 19, 'e', 12) .arg(_OMEGA0, 19, 'e', 12) .arg(_Cis, 19, 'e', 12); out << QString(fmt) .arg(_i0, 19, 'e', 12) .arg(_Crc, 19, 'e', 12) .arg(_omega, 19, 'e', 12) .arg(_OMEGADOT, 19, 'e', 12); out << QString(fmt) .arg(_IDOT, 19, 'e', 12) .arg(_L2Codes, 19, 'e', 12) .arg(_TOEweek, 19, 'e', 12) .arg(_L2PFlag, 19, 'e', 12); out << QString(fmt) .arg(_ura, 19, 'e', 12) .arg(_health, 19, 'e', 12) .arg(_TGD, 19, 'e', 12) .arg(_IODC, 19, 'e', 12); out << QString(fmt) .arg(_TOT, 19, 'e', 12) .arg(_fitInterval, 19, 'e', 12) .arg("", 19, QChar(' ')) .arg("", 19, QChar(' ')); return rnxStr; } // RINEX Format String ////////////////////////////////////////////////////////////////////////////// QString t_ephGlo::toString(double version) const { QString rnxStr = rinexDateStr(_TOC-_gps_utc, _prn, version); QTextStream out(&rnxStr); out << QString("%1%2%3\n") .arg(-_tau, 19, 'e', 12) .arg(_gamma, 19, 'e', 12) .arg(_tki, 19, 'e', 12); QString fmt = version < 3.0 ? " %1%2%3%4\n" : " %1%2%3%4\n"; out << QString(fmt) .arg(_x_pos, 19, 'e', 12) .arg(_x_velocity, 19, 'e', 12) .arg(_x_acceleration, 19, 'e', 12) .arg(_health, 19, 'e', 12); out << QString(fmt) .arg(_y_pos, 19, 'e', 12) .arg(_y_velocity, 19, 'e', 12) .arg(_y_acceleration, 19, 'e', 12) .arg(_frequency_number, 19, 'e', 12); out << QString(fmt) .arg(_z_pos, 19, 'e', 12) .arg(_z_velocity, 19, 'e', 12) .arg(_z_acceleration, 19, 'e', 12) .arg(_E, 19, 'e', 12); return rnxStr; } // RINEX Format String ////////////////////////////////////////////////////////////////////////////// QString t_ephGal::toString(double version) const { QString rnxStr = rinexDateStr(_TOC, _prn, version); QTextStream out(&rnxStr); out << QString("%1%2%3\n") .arg(_clock_bias, 19, 'e', 12) .arg(_clock_drift, 19, 'e', 12) .arg(_clock_driftrate, 19, 'e', 12); QString fmt = version < 3.0 ? " %1%2%3%4\n" : " %1%2%3%4\n"; out << QString(fmt) .arg(_IODnav, 19, 'e', 12) .arg(_Crs, 19, 'e', 12) .arg(_Delta_n, 19, 'e', 12) .arg(_M0, 19, 'e', 12); out << QString(fmt) .arg(_Cuc, 19, 'e', 12) .arg(_e, 19, 'e', 12) .arg(_Cus, 19, 'e', 12) .arg(_sqrt_A, 19, 'e', 12); out << QString(fmt) .arg(_TOEsec, 19, 'e', 12) .arg(_Cic, 19, 'e', 12) .arg(_OMEGA0, 19, 'e', 12) .arg(_Cis, 19, 'e', 12); out << QString(fmt) .arg(_i0, 19, 'e', 12) .arg(_Crc, 19, 'e', 12) .arg(_omega, 19, 'e', 12) .arg(_OMEGADOT, 19, 'e', 12); int dataSource = 0; double HS = 0.0; if ( (_flags & GALEPHF_INAV) == GALEPHF_INAV ) { dataSource |= (1<<0); dataSource |= (1<<9); HS = _E5bHS; } else if ( (_flags & GALEPHF_FNAV) == GALEPHF_FNAV ) { dataSource |= (1<<1); dataSource |= (1<<8); HS = _E5aHS; } out << QString(fmt) .arg(_IDOT, 19, 'e', 12) .arg(double(dataSource), 19, 'e', 12) .arg(_TOEweek, 19, 'e', 12) .arg(0.0, 19, 'e', 12); out << QString(fmt) .arg(_SISA, 19, 'e', 12) .arg(HS, 19, 'e', 12) .arg(_BGD_1_5A, 19, 'e', 12) .arg(_BGD_1_5B, 19, 'e', 12); out << QString(fmt) .arg(_TOT, 19, 'e', 12) .arg("", 19, QChar(' ')) .arg("", 19, QChar(' ')) .arg("", 19, QChar(' ')); return rnxStr; } // Constructor ////////////////////////////////////////////////////////////////////////////// t_ephSBAS::t_ephSBAS(float rnxVersion, const QStringList& lines) { const int nLines = 4; if (lines.size() != nLines) { _checkState = bad; return; } // RINEX Format // ------------ int fieldLen = 19; int pos[4]; pos[0] = (rnxVersion <= 2.12) ? 3 : 4; pos[1] = pos[0] + fieldLen; pos[2] = pos[1] + fieldLen; pos[3] = pos[2] + fieldLen; // Read four lines // --------------- for (int iLine = 0; iLine < nLines; iLine++) { QString line = lines[iLine]; if ( iLine == 0 ) { QTextStream in(line.left(pos[1]).toAscii()); int year, month, day, hour, min; double sec; QString prnStr; in >> prnStr >> year >> month >> day >> hour >> min >> sec; if (prnStr.at(0) == 'S') { _prn.set('S', prnStr.mid(1).toInt()); } else { _prn.set('S', prnStr.toInt()); } if (year < 80) { year += 2000; } else if (year < 100) { year += 1900; } _TOC.set(year, month, day, hour, min, sec); if ( readDbl(line, pos[1], fieldLen, _agf0 ) || readDbl(line, pos[2], fieldLen, _agf1 ) || readDbl(line, pos[3], fieldLen, _TOW ) ) { _checkState = bad; return; } } else if ( iLine == 1 ) { if ( readDbl(line, pos[0], fieldLen, _x_pos ) || readDbl(line, pos[1], fieldLen, _x_velocity ) || readDbl(line, pos[2], fieldLen, _x_acceleration) || readDbl(line, pos[3], fieldLen, _health ) ) { _checkState = bad; return; } } else if ( iLine == 2 ) { if ( readDbl(line, pos[0], fieldLen, _y_pos ) || readDbl(line, pos[1], fieldLen, _y_velocity ) || readDbl(line, pos[2], fieldLen, _y_acceleration ) || readDbl(line, pos[3], fieldLen, _ura ) ) { _checkState = bad; return; } } else if ( iLine == 3 ) { double iodn; if ( readDbl(line, pos[0], fieldLen, _z_pos ) || readDbl(line, pos[1], fieldLen, _z_velocity ) || readDbl(line, pos[2], fieldLen, _z_acceleration) || readDbl(line, pos[3], fieldLen, iodn ) ) { _checkState = bad; return; _IODN = int(iodn); } } } _x_pos *= 1.e3; _y_pos *= 1.e3; _z_pos *= 1.e3; _x_velocity *= 1.e3; _y_velocity *= 1.e3; _z_velocity *= 1.e3; _x_acceleration *= 1.e3; _y_acceleration *= 1.e3; _z_acceleration *= 1.e3; } // Set SBAS Satellite Position //////////////////////////////////////////////////////////////////////////// void t_ephSBAS::set(const sbasephemeris* ee) { _prn.set('S', ee->satellite - PRN_SBAS_START + 20); _TOC.set(ee->GPSweek_TOE, double(ee->TOE)); _IODN = ee->IODN; _TOW = ee->TOW; _agf0 = ee->agf0; _agf1 = ee->agf1; _x_pos = ee->x_pos; _x_velocity = ee->x_velocity; _x_acceleration = ee->x_acceleration; _y_pos = ee->y_pos; _y_velocity = ee->y_velocity; _y_acceleration = ee->y_acceleration; _z_pos = ee->z_pos; _z_velocity = ee->z_velocity; _z_acceleration = ee->z_acceleration; _ura = ee->URA; _health = 0; } // Compute SBAS Satellite Position (virtual) //////////////////////////////////////////////////////////////////////////// t_irc t_ephSBAS::position(int GPSweek, double GPSweeks, double* xc, double* vv) const { if (_checkState == bad) { return failure; } bncTime tt(GPSweek, GPSweeks); double dt = tt - _TOC; xc[0] = _x_pos + _x_velocity * dt + _x_acceleration * dt * dt / 2.0; xc[1] = _y_pos + _y_velocity * dt + _y_acceleration * dt * dt / 2.0; xc[2] = _z_pos + _z_velocity * dt + _z_acceleration * dt * dt / 2.0; vv[0] = _x_velocity + _x_acceleration * dt; vv[1] = _y_velocity + _y_acceleration * dt; vv[2] = _z_velocity + _z_acceleration * dt; xc[3] = _agf0 + _agf1 * dt; return success; } // RINEX Format String ////////////////////////////////////////////////////////////////////////////// QString t_ephSBAS::toString(double version) const { QString rnxStr = rinexDateStr(_TOC, _prn, version); QTextStream out(&rnxStr); out << QString("%1%2%3\n") .arg(_agf0, 19, 'e', 12) .arg(_agf1, 19, 'e', 12) .arg(_TOW, 19, 'e', 12); QString fmt = version < 3.0 ? " %1%2%3%4\n" : " %1%2%3%4\n"; out << QString(fmt) .arg(1.e-3*_x_pos, 19, 'e', 12) .arg(1.e-3*_x_velocity, 19, 'e', 12) .arg(1.e-3*_x_acceleration, 19, 'e', 12) .arg(_health, 19, 'e', 12); out << QString(fmt) .arg(1.e-3*_y_pos, 19, 'e', 12) .arg(1.e-3*_y_velocity, 19, 'e', 12) .arg(1.e-3*_y_acceleration, 19, 'e', 12) .arg(_ura, 19, 'e', 12); out << QString(fmt) .arg(1.e-3*_z_pos, 19, 'e', 12) .arg(1.e-3*_z_velocity, 19, 'e', 12) .arg(1.e-3*_z_acceleration, 19, 'e', 12) .arg(double(_IODN), 19, 'e', 12); return rnxStr; } // Constructor ////////////////////////////////////////////////////////////////////////////// t_ephBDS::t_ephBDS(float rnxVersion, const QStringList& lines) { const int nLines = 8; if (lines.size() != nLines) { _checkState = bad; return; } // RINEX Format // ------------ int fieldLen = 19; int pos[4]; pos[0] = (rnxVersion <= 2.12) ? 3 : 4; pos[1] = pos[0] + fieldLen; pos[2] = pos[1] + fieldLen; pos[3] = pos[2] + fieldLen; double TOTs; double TOEs; double TOEw; // Read eight lines // ---------------- for (int iLine = 0; iLine < nLines; iLine++) { QString line = lines[iLine]; if ( iLine == 0 ) { QTextStream in(line.left(pos[1]).toAscii()); int year, month, day, hour, min; double sec; QString prnStr; in >> prnStr >> year >> month >> day >> hour >> min >> sec; if (prnStr.at(0) == 'C') { _prn.set('C', prnStr.mid(1).toInt()); } else { _prn.set('C', prnStr.toInt()); } if (year < 80) { year += 2000; } else if (year < 100) { year += 1900; } _TOC_bdt.set(year, month, day, hour, min, sec); if ( readDbl(line, pos[1], fieldLen, _clock_bias ) || readDbl(line, pos[2], fieldLen, _clock_drift ) || readDbl(line, pos[3], fieldLen, _clock_driftrate) ) { _checkState = bad; return; } } else if ( iLine == 1 ) { double aode; if ( readDbl(line, pos[0], fieldLen, aode ) || readDbl(line, pos[1], fieldLen, _Crs ) || readDbl(line, pos[2], fieldLen, _Delta_n) || readDbl(line, pos[3], fieldLen, _M0 ) ) { _checkState = bad; return; } _AODE = int(aode); } else if ( iLine == 2 ) { if ( readDbl(line, pos[0], fieldLen, _Cuc ) || readDbl(line, pos[1], fieldLen, _e ) || readDbl(line, pos[2], fieldLen, _Cus ) || readDbl(line, pos[3], fieldLen, _sqrt_A) ) { _checkState = bad; return; } } else if ( iLine == 3 ) { if ( readDbl(line, pos[0], fieldLen, TOEs ) || readDbl(line, pos[1], fieldLen, _Cic ) || readDbl(line, pos[2], fieldLen, _OMEGA0) || readDbl(line, pos[3], fieldLen, _Cis ) ) { _checkState = bad; return; } } else if ( iLine == 4 ) { if ( readDbl(line, pos[0], fieldLen, _i0 ) || readDbl(line, pos[1], fieldLen, _Crc ) || readDbl(line, pos[2], fieldLen, _omega ) || readDbl(line, pos[3], fieldLen, _OMEGADOT) ) { _checkState = bad; return; } } else if ( iLine == 5 ) { if ( readDbl(line, pos[0], fieldLen, _IDOT ) || readDbl(line, pos[2], fieldLen, TOEw) ) { _checkState = bad; return; } } else if ( iLine == 6 ) { double SatH1; if ( readDbl(line, pos[1], fieldLen, SatH1) || readDbl(line, pos[2], fieldLen, _TGD1) || readDbl(line, pos[3], fieldLen, _TGD2) ) { _checkState = bad; return; } _SatH1 = int(SatH1); } else if ( iLine == 7 ) { double aodc; if ( readDbl(line, pos[0], fieldLen, TOTs) || readDbl(line, pos[1], fieldLen, aodc) ) { _checkState = bad; return; } if (TOTs == 0.9999e9) { // 0.9999e9 means not known (RINEX standard) TOTs = TOEs; } _AODC = int(aodc); } } TOEw += 1356; // BDT -> GPS week number _TOE_bdt.set(int(TOEw), TOEs); // GPS->BDT // -------- _TOC = _TOC_bdt + 14.0; _TOE = _TOE_bdt + 14.0; // remark: actually should be computed from second_tot // but it seems to be unreliable in RINEX files _TOT = _TOC; } // Set BDS Satellite Position //////////////////////////////////////////////////////////////////////////// void t_ephBDS::set(const bdsephemeris* ee) { _receptDateTime = currentDateAndTimeGPS(); _prn.set('C', ee->satellite - PRN_BDS_START + 1); _TOE_bdt.set(1356 + ee->BDSweek, ee->TOE); _TOE = _TOE_bdt + 14.0; _TOC_bdt.set(1356 + ee->BDSweek, ee->TOC); _TOC = _TOC_bdt + 14.0; _AODE = ee->AODE; _AODC = ee->AODC; _clock_bias = ee->clock_bias; _clock_drift = ee->clock_drift; _clock_driftrate = ee->clock_driftrate; _Crs = ee->Crs; _Delta_n = ee->Delta_n; _M0 = ee->M0; _Cuc = ee->Cuc; _e = ee->e; _Cus = ee->Cus; _sqrt_A = ee->sqrt_A; _Cic = ee->Cic; _OMEGA0 = ee->OMEGA0; _Cis = ee->Cis; _i0 = ee->i0; _Crc = ee->Crc; _omega = ee->omega; _OMEGADOT = ee->OMEGADOT; _IDOT = ee->IDOT; _TGD1 = ee->TGD_B1_B3; _TGD2 = ee->TGD_B2_B3; _URAI = ee->URAI; _SatH1 = (ee->flags & BDSEPHF_SATH1) ? 1: 0; } // Compute BDS Satellite Position (virtual) ////////////////////////////////////////////////////////////////////////////// t_irc t_ephBDS::position(int GPSweek, double GPSweeks, double* xc, double* vv) const { if (_checkState == bad) { return failure; } static const double gmBDS = 398.6004418e12; static const double omegaBDS = 7292115.0000e-11; xc[0] = xc[1] = xc[2] = xc[3] = 0.0; vv[0] = vv[1] = vv[2] = 0.0; bncTime tt(GPSweek, GPSweeks); if (_sqrt_A == 0) { return failure; } double a0 = _sqrt_A * _sqrt_A; double n0 = sqrt(gmBDS/(a0*a0*a0)); double tk = tt - _TOE; double n = n0 + _Delta_n; double M = _M0 + n*tk; double E = M; double E_last; int nLoop = 0; do { E_last = E; E = M + _e*sin(E); if (++nLoop == 100) { return failure; } } while ( fabs(E-E_last)*a0 > 0.001 ); double v = atan2(sqrt(1-_e*_e) * sin(E), cos(E) - _e); double u0 = v + _omega; double sin2u0 = sin(2*u0); double cos2u0 = cos(2*u0); double r = a0*(1 - _e*cos(E)) + _Crc*cos2u0 + _Crs*sin2u0; double i = _i0 + _IDOT*tk + _Cic*cos2u0 + _Cis*sin2u0; double u = u0 + _Cuc*cos2u0 + _Cus*sin2u0; double xp = r*cos(u); double yp = r*sin(u); double toesec = (_TOE.gpssec() - 14.0); double sinom = 0; double cosom = 0; double sini = 0; double cosi = 0; const double iMaxGEO = 10.0 / 180.0 * M_PI; // MEO/IGSO satellite // ------------------ if (_i0 > iMaxGEO) { double OM = _OMEGA0 + (_OMEGADOT - omegaBDS)*tk - omegaBDS*toesec; sinom = sin(OM); cosom = cos(OM); sini = sin(i); cosi = cos(i); xc[0] = xp*cosom - yp*cosi*sinom; xc[1] = xp*sinom + yp*cosi*cosom; xc[2] = yp*sini; } // GEO satellite // ------------- else { double OM = _OMEGA0 + _OMEGADOT*tk - omegaBDS*toesec; double ll = omegaBDS*tk; sinom = sin(OM); cosom = cos(OM); sini = sin(i); cosi = cos(i); double xx = xp*cosom - yp*cosi*sinom; double yy = xp*sinom + yp*cosi*cosom; double zz = yp*sini; Matrix R1 = BNC_PPP::t_astro::rotX(-5.0 / 180.0 * M_PI); Matrix R2 = BNC_PPP::t_astro::rotZ(ll); ColumnVector X1(3); X1 << xx << yy << zz; ColumnVector X2 = R2*R1*X1; xc[0] = X2(1); xc[1] = X2(2); xc[2] = X2(3); } double tc = tt - _TOC; xc[3] = _clock_bias + _clock_drift*tc + _clock_driftrate*tc*tc - 4.442807633e-10 * _e * sqrt(a0) *sin(E); // Velocity // -------- double tanv2 = tan(v/2); double dEdM = 1 / (1 - _e*cos(E)); double dotv = sqrt((1.0 + _e)/(1.0 - _e)) / cos(E/2)/cos(E/2) / (1 + tanv2*tanv2) * dEdM * n; double dotu = dotv + (-_Cuc*sin2u0 + _Cus*cos2u0)*2*dotv; double dotom = _OMEGADOT - t_CST::omega; double doti = _IDOT + (-_Cic*sin2u0 + _Cis*cos2u0)*2*dotv; double dotr = a0 * _e*sin(E) * dEdM * n + (-_Crc*sin2u0 + _Crs*cos2u0)*2*dotv; double dotx = dotr*cos(u) - r*sin(u)*dotu; double doty = dotr*sin(u) + r*cos(u)*dotu; vv[0] = cosom *dotx - cosi*sinom *doty // dX / dr - xp*sinom*dotom - yp*cosi*cosom*dotom // dX / dOMEGA + yp*sini*sinom*doti; // dX / di vv[1] = sinom *dotx + cosi*cosom *doty + xp*cosom*dotom - yp*cosi*sinom*dotom - yp*sini*cosom*doti; vv[2] = sini *doty + yp*cosi *doti; // dotC = _clock_drift + _clock_driftrate*tc // - 4.442807633e-10*_e*sqrt(a0)*cos(E) * dEdM * n; return success; } // RINEX Format String ////////////////////////////////////////////////////////////////////////////// QString t_ephBDS::toString(double version) const { QString rnxStr = rinexDateStr(_TOC_bdt, _prn, version); QTextStream out(&rnxStr); out << QString("%1%2%3\n") .arg(_clock_bias, 19, 'e', 12) .arg(_clock_drift, 19, 'e', 12) .arg(_clock_driftrate, 19, 'e', 12); QString fmt = version < 3.0 ? " %1%2%3%4\n" : " %1%2%3%4\n"; out << QString(fmt) .arg(double(_AODE), 19, 'e', 12) .arg(_Crs, 19, 'e', 12) .arg(_Delta_n, 19, 'e', 12) .arg(_M0, 19, 'e', 12); out << QString(fmt) .arg(_Cuc, 19, 'e', 12) .arg(_e, 19, 'e', 12) .arg(_Cus, 19, 'e', 12) .arg(_sqrt_A, 19, 'e', 12); out << QString(fmt) .arg(_TOE_bdt.gpssec(), 19, 'e', 12) .arg(_Cic, 19, 'e', 12) .arg(_OMEGA0, 19, 'e', 12) .arg(_Cis, 19, 'e', 12); out << QString(fmt) .arg(_i0, 19, 'e', 12) .arg(_Crc, 19, 'e', 12) .arg(_omega, 19, 'e', 12) .arg(_OMEGADOT, 19, 'e', 12); out << QString(fmt) .arg(_IDOT, 19, 'e', 12) .arg(0.0, 19, 'e', 12) .arg(double(_TOE_bdt.gpsw() - 1356.0), 19, 'e', 12) .arg(0.0, 19, 'e', 12); double ura = 0.0; if ((_URAI < 6) && (_URAI >= 0)) { ura = ceil(10.0 * pow(2.0, ((double)_URAI/2.0) + 1.0)) / 10.0; } if ((_URAI >= 6) && (_URAI < 15)) { ura = ceil(10.0 * pow(2.0, ((double)_URAI/2.0) )) / 10.0; } out << QString(fmt) .arg(ura, 19, 'e', 12) .arg(double(_SatH1), 19, 'e', 12) .arg(_TGD1, 19, 'e', 12) .arg(_TGD2, 19, 'e', 12); out << QString(fmt) .arg(_TOE_bdt.gpssec(), 19, 'e', 12) .arg(double(_AODC), 19, 'e', 12) .arg("", 19, QChar(' ')) .arg("", 19, QChar(' ')); return rnxStr; }