1 | // Part of BNC, a utility for retrieving decoding and
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2 | // converting GNSS data streams from NTRIP broadcasters.
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3 | //
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4 | // Copyright (C) 2007
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5 | // German Federal Agency for Cartography and Geodesy (BKG)
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6 | // http://www.bkg.bund.de
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7 | // Czech Technical University Prague, Department of Geodesy
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8 | // http://www.fsv.cvut.cz
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9 | //
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10 | // Email: euref-ip@bkg.bund.de
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11 | //
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12 | // This program is free software; you can redistribute it and/or
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13 | // modify it under the terms of the GNU General Public License
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14 | // as published by the Free Software Foundation, version 2.
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15 | //
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16 | // This program is distributed in the hope that it will be useful,
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17 | // but WITHOUT ANY WARRANTY; without even the implied warranty of
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18 | // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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19 | // GNU General Public License for more details.
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20 | //
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21 | // You should have received a copy of the GNU General Public License
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22 | // along with this program; if not, write to the Free Software
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23 | // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
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24 |
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25 | /* -------------------------------------------------------------------------
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26 | * BKG NTRIP Client
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27 | * -------------------------------------------------------------------------
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28 | *
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29 | * Class: bncutils
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30 | *
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31 | * Purpose: Auxiliary Functions
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32 | *
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33 | * Author: L. Mervart
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34 | *
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35 | * Created: 30-Aug-2006
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36 | *
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37 | * Changes:
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38 | *
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39 | * -----------------------------------------------------------------------*/
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40 |
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41 | #include <iostream>
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42 | #include <ctime>
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43 | #include <math.h>
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44 |
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45 | #include <QRegExp>
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46 | #include <QStringList>
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47 | #include <QDateTime>
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48 |
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49 | #include "bncutils.h"
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50 | #include "bnccore.h"
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51 |
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52 | using namespace std;
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53 |
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54 | //
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55 | ////////////////////////////////////////////////////////////////////////////
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56 | void expandEnvVar(QString& str) {
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57 |
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58 | QRegExp rx("(\\$\\{.+\\})");
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59 |
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60 | if (rx.indexIn(str) != -1) {
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61 | QStringListIterator it(rx.capturedTexts());
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62 | if (it.hasNext()) {
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63 | QString rxStr = it.next();
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64 | QString envVar = rxStr.mid(2,rxStr.length()-3);
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65 | str.replace(rxStr, qgetenv(envVar.toAscii()));
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66 | }
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67 | }
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68 |
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69 | }
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70 |
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71 | //
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72 | ////////////////////////////////////////////////////////////////////////////
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73 | QDateTime dateAndTimeFromGPSweek(int GPSWeek, double GPSWeeks) {
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74 |
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75 | static const QDate zeroEpoch(1980, 1, 6);
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76 |
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77 | QDate date(zeroEpoch);
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78 | QTime time(0,0,0,0);
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79 |
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80 | int weekDays = int(GPSWeeks) / 86400;
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81 | date = date.addDays( GPSWeek * 7 + weekDays );
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82 | time = time.addMSecs( int( (GPSWeeks - 86400 * weekDays) * 1e3 ) );
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83 |
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84 | return QDateTime(date,time);
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85 | }
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86 |
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87 | //
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88 | ////////////////////////////////////////////////////////////////////////////
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89 | void currentGPSWeeks(int& week, double& sec) {
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90 |
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91 | QDateTime currDateTimeGPS;
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92 |
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93 | if ( BNC_CORE->_currentDateAndTimeGPS ) {
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94 | currDateTimeGPS = *(BNC_CORE->_currentDateAndTimeGPS);
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95 | }
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96 | else {
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97 | currDateTimeGPS = QDateTime::currentDateTime().toUTC();
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98 | QDate hlp = currDateTimeGPS.date();
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99 | currDateTimeGPS = currDateTimeGPS.addSecs(gnumleap(hlp.year(),
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100 | hlp.month(), hlp.day()));
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101 | }
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102 |
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103 | QDate currDateGPS = currDateTimeGPS.date();
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104 | QTime currTimeGPS = currDateTimeGPS.time();
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105 |
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106 | week = int( (double(currDateGPS.toJulianDay()) - 2444244.5) / 7 );
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107 |
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108 | sec = (currDateGPS.dayOfWeek() % 7) * 24.0 * 3600.0 +
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109 | currTimeGPS.hour() * 3600.0 +
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110 | currTimeGPS.minute() * 60.0 +
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111 | currTimeGPS.second() +
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112 | currTimeGPS.msec() / 1000.0;
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113 | }
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114 |
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115 | //
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116 | ////////////////////////////////////////////////////////////////////////////
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117 | QDateTime currentDateAndTimeGPS() {
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118 | if ( BNC_CORE->_currentDateAndTimeGPS ) {
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119 | return *(BNC_CORE->_currentDateAndTimeGPS);
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120 | }
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121 | else {
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122 | int GPSWeek;
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123 | double GPSWeeks;
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124 | currentGPSWeeks(GPSWeek, GPSWeeks);
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125 | return dateAndTimeFromGPSweek(GPSWeek, GPSWeeks);
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126 | }
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127 | }
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128 |
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129 | //
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130 | ////////////////////////////////////////////////////////////////////////////
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131 | QByteArray ggaString(const QByteArray& latitude,
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132 | const QByteArray& longitude,
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133 | const QByteArray& height) {
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134 |
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135 | double lat = strtod(latitude,NULL);
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136 | double lon = strtod(longitude,NULL);
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137 | double hei = strtod(height,NULL);
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138 |
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139 | const char* flagN="N";
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140 | const char* flagE="E";
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141 | if (lon >180.) {lon=(lon-360.)*(-1.); flagE="W";}
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142 | if ((lon < 0.) && (lon >= -180.)) {lon=lon*(-1.); flagE="W";}
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143 | if (lon < -180.) {lon=(lon+360.); flagE="E";}
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144 | if (lat < 0.) {lat=lat*(-1.); flagN="S";}
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145 | QTime ttime(QDateTime::currentDateTime().toUTC().time());
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146 | int lat_deg = (int)lat;
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147 | double lat_min=(lat-lat_deg)*60.;
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148 | int lon_deg = (int)lon;
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149 | double lon_min=(lon-lon_deg)*60.;
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150 | int hh = 0 , mm = 0;
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151 | double ss = 0.0;
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152 | hh=ttime.hour();
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153 | mm=ttime.minute();
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154 | ss=(double)ttime.second()+0.001*ttime.msec();
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155 | QString gga;
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156 | gga += "GPGGA,";
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157 | gga += QString("%1%2%3,").arg((int)hh, 2, 10, QLatin1Char('0')).arg((int)mm, 2, 10, QLatin1Char('0')).arg((int)ss, 2, 10, QLatin1Char('0'));
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158 | gga += QString("%1%2,").arg((int)lat_deg,2, 10, QLatin1Char('0')).arg(lat_min, 7, 'f', 4, QLatin1Char('0'));
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159 | gga += flagN;
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160 | gga += QString(",%1%2,").arg((int)lon_deg,3, 10, QLatin1Char('0')).arg(lon_min, 7, 'f', 4, QLatin1Char('0'));
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161 | gga += flagE + QString(",1,05,1.00");
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162 | gga += QString(",%1,").arg(hei, 2, 'f', 1);
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163 | gga += QString("M,10.000,M,,");
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164 | int xori;
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165 | char XOR = 0;
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166 | char *Buff =gga.toAscii().data();
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167 | int iLen = strlen(Buff);
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168 | for (xori = 0; xori < iLen; xori++) {
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169 | XOR ^= (char)Buff[xori];
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170 | }
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171 | gga = "$" + gga + QString("*%1").arg(XOR, 2, 16, QLatin1Char('0'));
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172 |
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173 | return gga.toAscii();
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174 | }
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175 |
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176 | //
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177 | ////////////////////////////////////////////////////////////////////////////
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178 | void RSW_to_XYZ(const ColumnVector& rr, const ColumnVector& vv,
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179 | const ColumnVector& rsw, ColumnVector& xyz) {
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180 |
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181 | ColumnVector along = vv / vv.norm_Frobenius();
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182 | ColumnVector cross = crossproduct(rr, vv); cross /= cross.norm_Frobenius();
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183 | ColumnVector radial = crossproduct(along, cross);
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184 |
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185 | Matrix RR(3,3);
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186 | RR.Column(1) = radial;
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187 | RR.Column(2) = along;
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188 | RR.Column(3) = cross;
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189 |
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190 | xyz = RR * rsw;
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191 | }
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192 |
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193 | // Transformation xyz --> radial, along track, out-of-plane
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194 | ////////////////////////////////////////////////////////////////////////////
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195 | void XYZ_to_RSW(const ColumnVector& rr, const ColumnVector& vv,
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196 | const ColumnVector& xyz, ColumnVector& rsw) {
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197 |
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198 | ColumnVector along = vv / vv.norm_Frobenius();
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199 | ColumnVector cross = crossproduct(rr, vv); cross /= cross.norm_Frobenius();
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200 | ColumnVector radial = crossproduct(along, cross);
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201 |
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202 | rsw.ReSize(3);
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203 | rsw(1) = DotProduct(xyz, radial);
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204 | rsw(2) = DotProduct(xyz, along);
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205 | rsw(3) = DotProduct(xyz, cross);
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206 | }
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207 |
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208 | // Rectangular Coordinates -> Ellipsoidal Coordinates
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209 | ////////////////////////////////////////////////////////////////////////////
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210 | t_irc xyz2ell(const double* XYZ, double* Ell) {
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211 |
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212 | const double bell = t_CST::aell*(1.0-1.0/t_CST::fInv) ;
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213 | const double e2 = (t_CST::aell*t_CST::aell-bell*bell)/(t_CST::aell*t_CST::aell) ;
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214 | const double e2c = (t_CST::aell*t_CST::aell-bell*bell)/(bell*bell) ;
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215 |
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216 | double nn, ss, zps, hOld, phiOld, theta, sin3, cos3;
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217 |
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218 | ss = sqrt(XYZ[0]*XYZ[0]+XYZ[1]*XYZ[1]) ;
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219 | zps = XYZ[2]/ss ;
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220 | theta = atan( (XYZ[2]*t_CST::aell) / (ss*bell) );
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221 | sin3 = sin(theta) * sin(theta) * sin(theta);
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222 | cos3 = cos(theta) * cos(theta) * cos(theta);
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223 |
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224 | // Closed formula
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225 | Ell[0] = atan( (XYZ[2] + e2c * bell * sin3) / (ss - e2 * t_CST::aell * cos3) );
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226 | Ell[1] = atan2(XYZ[1],XYZ[0]) ;
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227 | nn = t_CST::aell/sqrt(1.0-e2*sin(Ell[0])*sin(Ell[0])) ;
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228 | Ell[2] = ss / cos(Ell[0]) - nn;
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229 |
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230 | const int MAXITER = 100;
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231 | for (int ii = 1; ii <= MAXITER; ii++) {
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232 | nn = t_CST::aell/sqrt(1.0-e2*sin(Ell[0])*sin(Ell[0])) ;
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233 | hOld = Ell[2] ;
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234 | phiOld = Ell[0] ;
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235 | Ell[2] = ss/cos(Ell[0])-nn ;
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236 | Ell[0] = atan(zps/(1.0-e2*nn/(nn+Ell[2]))) ;
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237 | if ( fabs(phiOld-Ell[0]) <= 1.0e-11 && fabs(hOld-Ell[2]) <= 1.0e-5 ) {
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238 | return success;
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239 | }
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240 | }
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241 |
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242 | return failure;
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243 | }
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244 |
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245 | // Rectangular Coordinates -> North, East, Up Components
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246 | ////////////////////////////////////////////////////////////////////////////
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247 | void xyz2neu(const double* Ell, const double* xyz, double* neu) {
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248 |
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249 | double sinPhi = sin(Ell[0]);
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250 | double cosPhi = cos(Ell[0]);
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251 | double sinLam = sin(Ell[1]);
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252 | double cosLam = cos(Ell[1]);
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253 |
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254 | neu[0] = - sinPhi*cosLam * xyz[0]
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255 | - sinPhi*sinLam * xyz[1]
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256 | + cosPhi * xyz[2];
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257 |
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258 | neu[1] = - sinLam * xyz[0]
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259 | + cosLam * xyz[1];
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260 |
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261 | neu[2] = + cosPhi*cosLam * xyz[0]
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262 | + cosPhi*sinLam * xyz[1]
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263 | + sinPhi * xyz[2];
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264 | }
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265 |
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266 | // North, East, Up Components -> Rectangular Coordinates
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267 | ////////////////////////////////////////////////////////////////////////////
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268 | void neu2xyz(const double* Ell, const double* neu, double* xyz) {
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269 |
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270 | double sinPhi = sin(Ell[0]);
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271 | double cosPhi = cos(Ell[0]);
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272 | double sinLam = sin(Ell[1]);
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273 | double cosLam = cos(Ell[1]);
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274 |
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275 | xyz[0] = - sinPhi*cosLam * neu[0]
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276 | - sinLam * neu[1]
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277 | + cosPhi*cosLam * neu[2];
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278 |
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279 | xyz[1] = - sinPhi*sinLam * neu[0]
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280 | + cosLam * neu[1]
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281 | + cosPhi*sinLam * neu[2];
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282 |
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283 | xyz[2] = + cosPhi * neu[0]
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284 | + sinPhi * neu[2];
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285 | }
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286 |
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287 | // Fourth order Runge-Kutta numerical integrator for ODEs
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288 | ////////////////////////////////////////////////////////////////////////////
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289 | ColumnVector rungeKutta4(
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290 | double xi, // the initial x-value
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291 | const ColumnVector& yi, // vector of the initial y-values
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292 | double dx, // the step size for the integration
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293 | double* acc, // aditional acceleration
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294 | ColumnVector (*der)(double x, const ColumnVector& y, double* acc)
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295 | // A pointer to a function that computes the
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296 | // derivative of a function at a point (x,y)
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297 | ) {
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298 |
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299 | ColumnVector k1 = der(xi , yi , acc) * dx;
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300 | ColumnVector k2 = der(xi+dx/2.0, yi+k1/2.0, acc) * dx;
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301 | ColumnVector k3 = der(xi+dx/2.0, yi+k2/2.0, acc) * dx;
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302 | ColumnVector k4 = der(xi+dx , yi+k3 , acc) * dx;
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303 |
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304 | ColumnVector yf = yi + k1/6.0 + k2/3.0 + k3/3.0 + k4/6.0;
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305 |
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306 | return yf;
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307 | }
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308 |
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309 | //
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310 | ////////////////////////////////////////////////////////////////////////////
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311 | double djul(int jj, int mm, double tt) {
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312 | int ii, kk;
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313 | double djul ;
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314 | if( mm <= 2 ) {
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315 | jj = jj - 1;
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316 | mm = mm + 12;
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317 | }
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318 | ii = jj/100;
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319 | kk = 2 - ii + ii/4;
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320 | djul = (365.25*jj - fmod( 365.25*jj, 1.0 )) - 679006.0;
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321 | djul = djul + floor( 30.6001*(mm + 1) ) + tt + kk;
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322 | return djul;
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323 | }
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324 |
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325 | //
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326 | ////////////////////////////////////////////////////////////////////////////
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327 | void jdgp(double tjul, double & second, int & nweek) {
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328 | double deltat;
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329 | deltat = tjul - 44244.0 ;
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330 | // current gps week
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331 | nweek = (int) floor(deltat/7.0);
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332 | // seconds past midnight of last weekend
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333 | second = (deltat - (nweek)*7.0)*86400.0;
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334 | }
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335 |
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336 | //
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337 | ////////////////////////////////////////////////////////////////////////////
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338 | void GPSweekFromDateAndTime(const QDateTime& dateTime,
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339 | int& GPSWeek, double& GPSWeeks) {
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340 |
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341 | static const QDateTime zeroEpoch(QDate(1980, 1, 6),QTime(),Qt::UTC);
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342 |
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343 | GPSWeek = zeroEpoch.daysTo(dateTime) / 7;
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344 |
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345 | int weekDay = dateTime.date().dayOfWeek() + 1; // Qt: Monday = 1
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346 | if (weekDay > 7) weekDay = 1;
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347 |
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348 | GPSWeeks = (weekDay - 1) * 86400.0
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349 | - dateTime.time().msecsTo(QTime()) / 1e3;
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350 | }
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351 |
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352 | //
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353 | ////////////////////////////////////////////////////////////////////////////
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354 | void GPSweekFromYMDhms(int year, int month, int day, int hour, int min,
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355 | double sec, int& GPSWeek, double& GPSWeeks) {
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356 |
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357 | double mjd = djul(year, month, day);
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358 |
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359 | jdgp(mjd, GPSWeeks, GPSWeek);
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360 | GPSWeeks += hour * 3600.0 + min * 60.0 + sec;
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361 | }
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362 |
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363 | //
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364 | ////////////////////////////////////////////////////////////////////////////
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365 | void mjdFromDateAndTime(const QDateTime& dateTime, int& mjd, double& dayfrac) {
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366 |
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367 | static const QDate zeroDate(1858, 11, 17);
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368 |
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369 | mjd = zeroDate.daysTo(dateTime.date());
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370 |
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371 | dayfrac = (dateTime.time().hour() +
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372 | (dateTime.time().minute() +
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373 | (dateTime.time().second() +
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374 | dateTime.time().msec() / 1000.0) / 60.0) / 60.0) / 24.0;
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375 | }
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376 |
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377 | //
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378 | ////////////////////////////////////////////////////////////////////////////
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379 | bool findInVector(const vector<QString>& vv, const QString& str) {
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380 | std::vector<QString>::const_iterator it;
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381 | for (it = vv.begin(); it != vv.end(); ++it) {
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382 | if ( (*it) == str) {
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383 | return true;
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384 | }
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385 | }
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386 | return false;
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387 | }
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388 |
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389 | //
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390 | ////////////////////////////////////////////////////////////////////////////
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391 | int readInt(const QString& str, int pos, int len, int& value) {
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392 | bool ok;
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393 | value = str.mid(pos, len).toInt(&ok);
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394 | return ok ? 0 : 1;
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395 | }
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396 |
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397 | //
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398 | ////////////////////////////////////////////////////////////////////////////
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399 | int readDbl(const QString& str, int pos, int len, double& value) {
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400 | QString hlp = str.mid(pos, len);
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401 | for (int ii = 0; ii < hlp.length(); ii++) {
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402 | if (hlp[ii]=='D' || hlp[ii]=='d' || hlp[ii] == 'E') {
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403 | hlp[ii]='e';
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404 | }
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405 | }
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406 | bool ok;
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407 | value = hlp.toDouble(&ok);
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408 | return ok ? 0 : 1;
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409 | }
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410 |
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411 | // Topocentrical Distance and Elevation
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412 | ////////////////////////////////////////////////////////////////////////////
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413 | void topos(double xRec, double yRec, double zRec,
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414 | double xSat, double ySat, double zSat,
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415 | double& rho, double& eleSat, double& azSat) {
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416 |
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417 | double dx[3];
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418 | dx[0] = xSat-xRec;
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419 | dx[1] = ySat-yRec;
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420 | dx[2] = zSat-zRec;
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421 |
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422 | rho = sqrt( dx[0]*dx[0] + dx[1]*dx[1] + dx[2]*dx[2] );
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423 |
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424 | double xyzRec[3];
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425 | xyzRec[0] = xRec;
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426 | xyzRec[1] = yRec;
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427 | xyzRec[2] = zRec;
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428 |
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429 | double Ell[3];
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430 | double neu[3];
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431 | xyz2ell(xyzRec, Ell);
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432 | xyz2neu(Ell, dx, neu);
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433 |
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434 | eleSat = acos( sqrt(neu[0]*neu[0] + neu[1]*neu[1]) / rho );
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435 | if (neu[2] < 0) {
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436 | eleSat *= -1.0;
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437 | }
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438 |
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439 | azSat = atan2(neu[1], neu[0]);
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440 | }
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441 |
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442 | // Degrees -> degrees, minutes, seconds
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443 | ////////////////////////////////////////////////////////////////////////////
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444 | void deg2DMS(double decDeg, int& deg, int& min, double& sec) {
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445 | int sgn = (decDeg < 0.0 ? -1 : 1);
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446 | deg = sgn * static_cast<int>(decDeg);
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447 | min = static_cast<int>((decDeg - deg)*60);
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448 | sec = (decDeg - deg - min/60.0) * 3600.0;
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449 | }
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