// Part of BNC, a utility for retrieving decoding and // converting GNSS data streams from NTRIP broadcasters. // // Copyright (C) 2007 // German Federal Agency for Cartography and Geodesy (BKG) // http://www.bkg.bund.de // Czech Technical University Prague, Department of Geodesy // http://www.fsv.cvut.cz // // Email: euref-ip@bkg.bund.de // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License // as published by the Free Software Foundation, version 2. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. /* ------------------------------------------------------------------------- * BKG NTRIP Client * ------------------------------------------------------------------------- * * Class: RTCM2Decoder * * Purpose: RTCM2 Decoder * * Author: L. Mervart * * Created: 24-Aug-2006 * * Changes: * * -----------------------------------------------------------------------*/ #include #include #include #include #include "../bncutils.h" #include "rtcm_utils.h" #include "RTCM2Decoder.h" using namespace std; using namespace rtcm2; // // Constructor // RTCM2Decoder::RTCM2Decoder(const std::string& ID) : _ephUser(true) { _ID = ID; } // // Destructor // RTCM2Decoder::~RTCM2Decoder() { } // t_irc RTCM2Decoder::getStaCrd(double& xx, double& yy, double& zz) { if (!_msg03.validMsg) { return failure; } xx = _msg03.x + (_msg22.validMsg ? _msg22.dL1[0] : 0.0); yy = _msg03.y + (_msg22.validMsg ? _msg22.dL1[1] : 0.0); zz = _msg03.z + (_msg22.validMsg ? _msg22.dL1[2] : 0.0); return success; } // t_irc RTCM2Decoder::getStaCrd(double& xx, double& yy, double& zz, double& dx1, double& dy1, double& dz1, double& dx2, double& dy2, double& dz2) { xx = _msg03.x; yy = _msg03.y; zz = _msg03.z; dx1 = (_msg22.validMsg ? _msg22.dL1[0] : 0.0); dy1 = (_msg22.validMsg ? _msg22.dL1[1] : 0.0); dz1 = (_msg22.validMsg ? _msg22.dL1[2] : 0.0); dx2 = (_msg22.validMsg ? _msg22.dL2[0] : 0.0); dy2 = (_msg22.validMsg ? _msg22.dL2[1] : 0.0); dz2 = (_msg22.validMsg ? _msg22.dL2[2] : 0.0); return success; } // t_irc RTCM2Decoder::Decode(char* buffer, int bufLen, vector& errmsg) { errmsg.clear(); _buffer.append(buffer, bufLen); int refWeek; double refSecs; currentGPSWeeks(refWeek, refSecs); bool decoded = false; while (true) { _PP.getPacket(_buffer); if (!_PP.valid()) { if (decoded) { return success; } else { return failure; } } // Store message number _typeList.push_back(_PP.ID()); if (_PP.ID() == 18 || _PP.ID() == 19) { _ObsBlock.extract(_PP); if (_ObsBlock.valid()) { decoded = true; int epochWeek; double epochSecs; _ObsBlock.resolveEpoch(refWeek, refSecs, epochWeek, epochSecs); for (int iSat = 0; iSat < _ObsBlock.nSat; iSat++) { t_satObs obs; if (_ObsBlock.PRN[iSat] > 100) { obs._prn.set('R', _ObsBlock.PRN[iSat] % 100); } else { obs._prn.set('G', _ObsBlock.PRN[iSat]); } char sys = obs._prn.system(); obs._time.set(epochWeek, epochSecs); t_frqObs* frqObs1C = new t_frqObs; frqObs1C->_rnxType2ch = "1C"; frqObs1C->_codeValid = true; frqObs1C->_code = _ObsBlock.rng_C1[iSat]; obs._obs.push_back(frqObs1C); t_frqObs* frqObs1P = new t_frqObs; frqObs1P->_rnxType2ch = (sys == 'G') ? "1W" : "1P"; frqObs1P->_codeValid = true; frqObs1P->_code = _ObsBlock.rng_P1[iSat]; frqObs1P->_phaseValid = true; frqObs1P->_phase = _ObsBlock.resolvedPhase_L1(iSat); frqObs1P->_slipCounter = _ObsBlock.slip_L1[iSat]; obs._obs.push_back(frqObs1P); t_frqObs* frqObs2P = new t_frqObs; frqObs2P->_rnxType2ch = (sys == 'G') ? "2W" : "2P"; frqObs2P->_codeValid = true; frqObs2P->_code = _ObsBlock.rng_P2[iSat]; frqObs2P->_phaseValid = true; frqObs2P->_phase = _ObsBlock.resolvedPhase_L2(iSat); frqObs2P->_slipCounter = _ObsBlock.slip_L2[iSat]; obs._obs.push_back(frqObs2P); _obsList.push_back(obs); } _ObsBlock.clear(); } } else if (_PP.ID() == 20 || _PP.ID() == 21) { _msg2021.extract(_PP); if (_msg2021.valid()) { decoded = true; translateCorr2Obs(errmsg); } } else if (_PP.ID() == 3) { _msg03.extract(_PP); } else if (_PP.ID() == 22) { _msg22.extract(_PP); } else if (_PP.ID() == 23) { _msg23.extract(_PP); } else if (_PP.ID() == 24) { _msg24.extract(_PP); } // Output for RTCM scan if (_PP.ID() == 3) { if (_msg03.validMsg) { _antList.push_back(t_antInfo()); this->getStaCrd(_antList.back().xx, _antList.back().yy, _antList.back().zz); _antList.back().type = t_antInfo::APC; _antList.back().message = _PP.ID(); } } else if (_PP.ID() == 23) { if (_msg23.validMsg) { _antType.push_back(_msg23.antType.c_str()); } } else if (_PP.ID() == 24) { if (_msg24.validMsg) { _antList.push_back(t_antInfo()); _antList.back().xx = _msg24.x; _antList.back().yy = _msg24.y; _antList.back().zz = _msg24.z; _antList.back().height_f = true; _antList.back().height = _msg24.h; _antList.back().type = t_antInfo::ARP; _antList.back().message = _PP.ID(); } } } return success; } void RTCM2Decoder::translateCorr2Obs(vector& errmsg) { QMutexLocker locker(&_mutex); if (!_msg03.validMsg || !_msg2021.valid()) { return; } double stax = _msg03.x + (_msg22.validMsg ? _msg22.dL1[0] : 0.0); double stay = _msg03.y + (_msg22.validMsg ? _msg22.dL1[1] : 0.0); double staz = _msg03.z + (_msg22.validMsg ? _msg22.dL1[2] : 0.0); int refWeek; double refSecs; currentGPSWeeks(refWeek, refSecs); // Resolve receiver time of measurement (see RTCM 2.3, page 4-42, Message 18, Note 1) // ---------------------------------------------------------------------------------- double hoursec_est = _msg2021.hoursec(); // estimated time of measurement double hoursec_rcv = rint(hoursec_est * 1e2) / 1e2; // receiver clock reading at hoursec_est double rcv_clk_bias = (hoursec_est - hoursec_rcv) * c_light; int GPSWeek; double GPSWeeks; resolveEpoch(hoursec_est, refWeek, refSecs, GPSWeek, GPSWeeks); int GPSWeek_rcv; double GPSWeeks_rcv; resolveEpoch(hoursec_rcv, refWeek, refSecs, GPSWeek_rcv, GPSWeeks_rcv); // Loop over all satellites // ------------------------ for (RTCM2_2021::data_iterator icorr = _msg2021.data.begin(); icorr != _msg2021.data.end(); icorr++) { const RTCM2_2021::HiResCorr* corr = icorr->second; // beg test if (corr->PRN >= 200) { continue; } // end test QString prn; char sys; if (corr->PRN < 200) { sys = 'G'; prn = sys + QString("%1_0").arg(corr->PRN, 2, 10, QChar('0')); } else { sys = 'R'; prn = sys + QString("%1_0").arg(corr->PRN - 200, 2, 10, QChar('0')); } double L1 = 0; double L2 = 0; double P1 = 0; double P2 = 0; string obsT = ""; // new observation t_satObs* new_obs = 0; t_frqObs* frqObs1C = new t_frqObs; frqObs1C->_rnxType2ch = "1C"; new_obs->_obs.push_back(frqObs1C); t_frqObs* frqObs1P = new t_frqObs; frqObs1P->_rnxType2ch = (sys == 'G') ? "1W" : "1P"; new_obs->_obs.push_back(frqObs1P); t_frqObs* frqObs2P = new t_frqObs; frqObs2P->_rnxType2ch = (sys == 'G') ? "2W" : "2P"; new_obs->_obs.push_back(frqObs2P); // missing IOD vector missingIOD; vector hasIOD; for (unsigned ii = 0; ii < 4; ii++) { unsigned int IODcorr = 0; double corrVal = 0; const t_eph* eph = 0; double* obsVal = 0; switch (ii) { case 0: // --- L1 --- IODcorr = corr->IODp1; corrVal = corr->phase1 * LAMBDA_1; obsVal = &L1; obsT = "L1"; break; case 1: // --- L2 --- IODcorr = corr->IODp2; corrVal = corr->phase2 * LAMBDA_2; obsVal = &L2; obsT = "L2"; break; case 2: // --- P1 --- IODcorr = corr->IODr1; corrVal = corr->range1; obsVal = &P1; obsT = "P1"; break; case 3: // --- P2 --- IODcorr = corr->IODr2; corrVal = corr->range2; obsVal = &P2; obsT = "P2"; break; default: continue; } // Select corresponding ephemerides const t_eph* ephLast = _ephUser.ephLast(prn); const t_eph* ephPrev = _ephUser.ephPrev(prn); if (ephLast && ephLast->IOD() == IODcorr) { eph = ephLast; } else if (ephPrev && ephPrev->IOD() == IODcorr) { eph = ephPrev; } if (eph) { ostringstream msg; msg << obsT << ':' << setw(3) << eph->IOD(); hasIOD.push_back(msg.str()); int GPSWeek_tot; double GPSWeeks_tot; double rho, xSat, ySat, zSat, clkSat; cmpRho(eph, stax, stay, staz, GPSWeek, GPSWeeks, rho, GPSWeek_tot, GPSWeeks_tot, xSat, ySat, zSat, clkSat); *obsVal = rho - corrVal + rcv_clk_bias - clkSat; if (*obsVal == 0) *obsVal = ZEROVALUE; // Allocate new memory // ------------------- if (!new_obs) { new_obs = new t_satObs(); if (corr->PRN < 200) { new_obs->_prn.set('G', corr->PRN); } else { new_obs->_prn.set('R', corr->PRN - 200); } new_obs->_time.set(GPSWeek_rcv, GPSWeeks_rcv); } // Store estimated measurements // ---------------------------- switch (ii) { case 0: // --- L1 --- frqObs1P->_phaseValid = true; frqObs1P->_phase = *obsVal / LAMBDA_1; frqObs1P->_slipCounter = corr->lock1; break; case 1: // --- L2 --- frqObs2P->_phaseValid = true; frqObs2P->_phase = *obsVal / LAMBDA_2; frqObs2P->_slipCounter = corr->lock2; break; case 2: // --- C1 / P1 --- if (corr->Pind1) { frqObs1P->_codeValid = true; frqObs1P->_code = *obsVal; } else { frqObs1C->_codeValid = true; frqObs1C->_code = *obsVal; } break; case 3: // --- C2 / P2 --- if (corr->Pind2) { frqObs2P->_codeValid = true; frqObs2P->_code = *obsVal; } break; default: continue; } } else if (IODcorr != 0) { ostringstream msg; msg << obsT << ':' << setw(3) << IODcorr; missingIOD.push_back(msg.str()); } } // loop over frequencies // Error report if (missingIOD.size()) { ostringstream missingIODstr; copy(missingIOD.begin(), missingIOD.end(), ostream_iterator(missingIODstr, " ")); errmsg.push_back( "missing eph for " + string(prn.toAscii().data()) + " , IODs " + missingIODstr.str()); } // Store new observation if (new_obs) { _obsList.push_back(*new_obs); delete new_obs; } } }