// 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: t_reqcAnalyze * * Purpose: Analyze RINEX Files * * Author: L. Mervart * * Created: 11-Apr-2012 * * Changes: * * -----------------------------------------------------------------------*/ #include #include #include #include "reqcanalyze.h" #include "bncapp.h" #include "bncsettings.h" #include "reqcedit.h" #include "bncutils.h" #include "bncpostprocess.h" #include "graphwin.h" #include "polarplot.h" #include "availplot.h" using namespace std; const double SLIPTRESH = 5.0; // cycle-slip threshold (meters) // Constructor //////////////////////////////////////////////////////////////////////////// t_reqcAnalyze::t_reqcAnalyze(QObject* parent) : QThread(parent) { bncSettings settings; _logFileName = settings.value("reqcOutLogFile").toString(); expandEnvVar(_logFileName); _logFile = 0; _log = 0; _obsFileNames = settings.value("reqcObsFile").toString().split(",", QString::SkipEmptyParts); _navFileNames = settings.value("reqcNavFile").toString().split(",", QString::SkipEmptyParts); _currEpo = 0; connect(this, SIGNAL(dspSkyPlot(const QString&, const QByteArray&, QVector*, const QByteArray&, QVector*, const QByteArray&, double)), this, SLOT(slotDspSkyPlot(const QString&, const QByteArray&, QVector*, const QByteArray&, QVector*, const QByteArray&, double))); connect(this, SIGNAL(dspAvailPlot(const QString&, const QByteArray&, QMap >*)), this, SLOT(slotDspAvailPlot(const QString&, const QByteArray&, QMap >*))); } // Destructor //////////////////////////////////////////////////////////////////////////// t_reqcAnalyze::~t_reqcAnalyze() { for (int ii = 0; ii < _rnxObsFiles.size(); ii++) { delete _rnxObsFiles[ii]; } for (int ii = 0; ii < _ephs.size(); ii++) { delete _ephs[ii]; } delete _log; _log = 0; delete _logFile; _logFile = 0; bncApp* app = (bncApp*) qApp; if ( app->mode() != bncApp::interactive) { app->exit(0); } } // //////////////////////////////////////////////////////////////////////////// void t_reqcAnalyze::slotDspSkyPlot(const QString& fileName, const QByteArray& title1, QVector* data1, const QByteArray& title2, QVector* data2, const QByteArray& scaleTitle, double maxValue) { bncApp* app = dynamic_cast(qApp); if (app->GUIenabled()) { if (maxValue == 0.0) { if (data1) { for (int ii = 0; ii < data1->size(); ii++) { double val = data1->at(ii)->_value; if (maxValue < val) { maxValue = val; } } } if (data2) { for (int ii = 0; ii < data2->size(); ii++) { double val = data2->at(ii)->_value; if (maxValue < val) { maxValue = val; } } } } QwtInterval scaleInterval(0.0, maxValue); QVector plots; if (data1) { t_polarPlot* plot1 = new t_polarPlot(QwtText(title1), scaleInterval, app->mainWindow()); plot1->addCurve(data1); plots << plot1; } if (data2) { t_polarPlot* plot2 = new t_polarPlot(QwtText(title2), scaleInterval, app->mainWindow()); plot2->addCurve(data2); plots << plot2; } t_graphWin* graphWin = new t_graphWin(0, fileName, plots, &scaleTitle, &scaleInterval); graphWin->show(); bncSettings settings; QString dirName = settings.value("reqcPlotDir").toString(); if (!dirName.isEmpty()) { QByteArray ext = scaleTitle.isEmpty() ? "_SNR.png" : "_MP.png"; graphWin->savePNG(dirName, ext); } } } // //////////////////////////////////////////////////////////////////////////// void t_reqcAnalyze::run() { // Open Log File // ------------- _logFile = new QFile(_logFileName); if (_logFile->open(QIODevice::WriteOnly | QIODevice::Text)) { _log = new QTextStream(); _log->setDevice(_logFile); } // Initialize RINEX Observation Files // ---------------------------------- t_reqcEdit::initRnxObsFiles(_obsFileNames, _rnxObsFiles, _log); // Read Ephemerides // ---------------- t_reqcEdit::readEphemerides(_navFileNames, _ephs); // Loop over all RINEX Files // ------------------------- for (int ii = 0; ii < _rnxObsFiles.size(); ii++) { analyzeFile(_rnxObsFiles[ii]); } // Exit // ---- emit finished(); deleteLater(); } // //////////////////////////////////////////////////////////////////////////// void t_reqcAnalyze::analyzeFile(t_rnxObsFile* obsFile) { if (_log) { *_log << "\nAnalyze File\n" << "------------\n" << obsFile->fileName().toAscii().data() << endl << endl; } _satStat.clear(); // A priori Coordinates // -------------------- ColumnVector xyz = obsFile->xyz(); // Loop over all Epochs // -------------------- try { while ( (_currEpo = obsFile->nextEpoch()) != 0) { // Loop over all satellites // ------------------------ for (unsigned iObs = 0; iObs < _currEpo->rnxSat.size(); iObs++) { const t_rnxObsFile::t_rnxSat& rnxSat = _currEpo->rnxSat[iObs]; t_obs obs; t_postProcessing::setObsFromRnx(obsFile, _currEpo, rnxSat, obs); if (obs.satSys == 'R') { continue; // TODO: set channel number } QString prn = QString("%1%2").arg(obs.satSys) .arg(obs.satNum, 2, 10, QChar('0')); t_satStat& satStat = _satStat[prn]; satStat.addObs(obs); } } // while (_currEpo) } catch (QString str) { if (_log) { *_log << "Exception " << str << endl; } else { qDebug() << str; } return; } // Analyze the Multipath // --------------------- QVector* dataMP1 = new QVector; QVector* dataMP2 = new QVector; QVector* dataSNR1 = new QVector; QVector* dataSNR2 = new QVector; QMap >* availL1 = new QMap >; QMapIterator it(_satStat); while (it.hasNext()) { it.next(); QString prn = it.key(); const t_satStat& satStat = it.value(); QVector& dataL1 = (*availL1)[prn]; preparePlotData(prn, satStat, xyz, obsFile->interval(), dataMP1, dataMP2, dataSNR1, dataSNR2, dataL1); } emit dspSkyPlot(obsFile->fileName(), "MP1", dataMP1, "MP2", dataMP2, "Meters", 2.0); emit dspSkyPlot(obsFile->fileName(), "SNR1", dataSNR1, "SNR2", dataSNR2, "", 9.0); emit dspAvailPlot(obsFile->fileName(), "Availability L1", availL1); if (_log) { _log->flush(); } } // //////////////////////////////////////////////////////////////////////////// void t_reqcAnalyze::t_satStat::addObs(const t_obs& obs) { t_anaObs* newObs = new t_anaObs(obs.GPSWeek, obs.GPSWeeks); bool okFlag = false; // Compute the Multipath // ---------------------- double L1 = obs.measdata("L1", 3.0); if (L1 != 0) { newObs->_hasL1 = true; } double L2 = obs.measdata("L2", 3.0); if (L2 != 0) { newObs->_hasL2 = true; } if (L1 != 0.0 && L2 != 0.0) { double f1 = t_CST::f1(obs.satSys, obs.slotNum); double f2 = t_CST::f2(obs.satSys, obs.slotNum); L1 = L1 * t_CST::c / f1; L2 = L2 * t_CST::c / f2; double P1 = obs.measdata("C1", 3.0); if (P1 != 0.0) { newObs->_MP1 = P1 - L1 - 2.0*f2*f2/(f1*f1-f2*f2) * (L1 - L2); okFlag = true; } double P2 = obs.measdata("C2", 3.0); if (P2 != 0.0) { newObs->_MP2 = P2 - L2 - 2.0*f1*f1/(f1*f1-f2*f2) * (L1 - L2); okFlag = true; } } // Signal-to-Noise // --------------- double S1 = obs.measdata("S1", 3.0); if (S1 != 0.0) { newObs->_SNR1 = floor(S1/6); if (newObs->_SNR1 > 9.0) { newObs->_SNR1 = 9.0; } if (newObs->_SNR1 < 1.0) { newObs->_SNR1 = 1.0; } okFlag = true; } else { if (obs.snrL1 > 0) { newObs->_SNR1 = obs.snrL1; okFlag = true; } } double S2 = obs.measdata("S2", 3.0); if (S2 != 0.0) { newObs->_SNR2 = floor(S2/6); if (newObs->_SNR2 > 9.0) { newObs->_SNR2 = 9.0; } if (newObs->_SNR2 < 1.0) { newObs->_SNR2 = 1.0; } okFlag = true; } else { if (obs.snrL2 > 0) { newObs->_SNR2 = obs.snrL2; okFlag = true; } } // Remember the Observation // ------------------------ if (okFlag) { anaObs << newObs; } else { delete newObs; } } // //////////////////////////////////////////////////////////////////////////// void t_reqcAnalyze::preparePlotData(const QString& prn, const t_satStat& satStat, const ColumnVector& xyz, double obsInterval, QVector* dataMP1, QVector* dataMP2, QVector* dataSNR1, QVector* dataSNR2, QVector& dataL1) { const int chunkStep = int( 30.0 / obsInterval); // chunk step (30 sec) const int numEpo = int(600.0 / obsInterval); // # epochs in one chunk (10 min) for (int chunkStart = 0; chunkStart + numEpo < satStat.anaObs.size(); chunkStart += chunkStep) { bncTime firstEpoch; // Compute Mean // ------------ bool slipFlag = false; double mean1 = 0.0; double mean2 = 0.0; double SNR1 = 0.0; double SNR2 = 0.0; for (int ii = 0; ii < numEpo; ii++) { int iEpo = chunkStart + ii; const t_anaObs* anaObs = satStat.anaObs[iEpo]; if (ii == 0) { firstEpoch.set(anaObs->_GPSWeek, anaObs->_GPSWeeks); } mean1 += anaObs->_MP1; mean2 += anaObs->_MP2; if ( anaObs->_SNR1 > 0 && (SNR1 == 0 || SNR1 > anaObs->_SNR1) ) { SNR1 = anaObs->_SNR1; } if ( anaObs->_SNR2 > 0 && (SNR2 == 0 || SNR2 > anaObs->_SNR2) ) { SNR2 = anaObs->_SNR2; } // Check Slip // ---------- if (ii > 0) { double diff1 = anaObs->_MP1 - satStat.anaObs[iEpo-1]->_MP1; double diff2 = anaObs->_MP2 - satStat.anaObs[iEpo-1]->_MP2; if (fabs(diff1) > SLIPTRESH || fabs(diff2) > SLIPTRESH) { slipFlag = true; break; } } } dataL1 << int(firstEpoch.gpssec()); if (slipFlag) { continue; } mean1 /= numEpo; mean2 /= numEpo; // Compute Standard Deviation // -------------------------- double stddev1 = 0.0; double stddev2 = 0.0; for (int ii = 0; ii < numEpo; ii++) { int iEpo = chunkStart + ii; const t_anaObs* anaObs = satStat.anaObs[iEpo]; double diff1 = anaObs->_MP1 - mean1; double diff2 = anaObs->_MP2 - mean2; stddev1 += diff1 * diff1; stddev2 += diff2 * diff2; } double MP1 = sqrt(stddev1 / (numEpo-1)); double MP2 = sqrt(stddev2 / (numEpo-1)); const t_anaObs* anaObs0 = satStat.anaObs[chunkStart]; // Compute the Azimuth and Zenith Distance // --------------------------------------- double az = 0.0; double zen = 0.0; if (xyz.size()) { t_eph* eph = 0; for (int ie = 0; ie < _ephs.size(); ie++) { if (_ephs[ie]->prn() == prn) { eph = _ephs[ie]; break; } } if (eph) { double xSat, ySat, zSat, clkSat; eph->position(anaObs0->_GPSWeek, anaObs0->_GPSWeeks, xSat, ySat, zSat, clkSat); double rho, eleSat, azSat; topos(xyz(1), xyz(2), xyz(3), xSat, ySat, zSat, rho, eleSat, azSat); az = azSat * 180.0/M_PI; zen = 90.0 - eleSat * 180.0/M_PI; } } // Add new Point // ------------- (*dataMP1) << (new t_polarPoint(az, zen, MP1)); (*dataMP2) << (new t_polarPoint(az, zen, MP2)); (*dataSNR1) << (new t_polarPoint(az, zen, SNR1)); (*dataSNR2) << (new t_polarPoint(az, zen, SNR2)); if (_log) { _log->setRealNumberNotation(QTextStream::FixedNotation); _log->setRealNumberPrecision(2); *_log << "MP1 " << prn << " " << az << " " << zen << " "; _log->setRealNumberPrecision(3); *_log << MP1 << endl; _log->setRealNumberPrecision(2); *_log << "MP2 " << prn << " " << az << " " << zen << " "; _log->setRealNumberPrecision(3); *_log << MP2 << endl; _log->flush(); } } } // //////////////////////////////////////////////////////////////////////////// void t_reqcAnalyze::slotDspAvailPlot(const QString& fileName, const QByteArray& title, QMap >* prnAvail){ if (dynamic_cast(qApp)->GUIenabled()) { t_availPlot* plot = new t_availPlot(0, prnAvail); QVector plots; plots << plot; t_graphWin* graphWin = new t_graphWin(0, fileName, plots, 0, 0); graphWin->show(); bncSettings settings; QString dirName = settings.value("reqcPlotDir").toString(); if (!dirName.isEmpty()) { QByteArray ext = "_AVAIL.png"; graphWin->savePNG(dirName, ext); } } }