1 | #include "erfa.h"
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2 |
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3 | int eraApio13(double utc1, double utc2, double dut1,
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4 | double elong, double phi, double hm, double xp, double yp,
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5 | double phpa, double tc, double rh, double wl,
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6 | eraASTROM *astrom)
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7 | /*
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8 | ** - - - - - - - - - -
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9 | ** e r a A p i o 1 3
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10 | ** - - - - - - - - - -
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11 | **
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12 | ** For a terrestrial observer, prepare star-independent astrometry
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13 | ** parameters for transformations between CIRS and observed
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14 | ** coordinates. The caller supplies UTC, site coordinates, ambient air
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15 | ** conditions and observing wavelength.
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16 | **
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17 | ** Given:
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18 | ** utc1 double UTC as a 2-part...
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19 | ** utc2 double ...quasi Julian Date (Notes 1,2)
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20 | ** dut1 double UT1-UTC (seconds)
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21 | ** elong double longitude (radians, east +ve, Note 3)
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22 | ** phi double geodetic latitude (radians, Note 3)
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23 | ** hm double height above ellipsoid (m, geodetic Notes 4,6)
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24 | ** xp,yp double polar motion coordinates (radians, Note 5)
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25 | ** phpa double pressure at the observer (hPa = mB, Note 6)
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26 | ** tc double ambient temperature at the observer (deg C)
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27 | ** rh double relative humidity at the observer (range 0-1)
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28 | ** wl double wavelength (micrometers, Note 7)
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29 | **
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30 | ** Returned:
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31 | ** astrom eraASTROM* star-independent astrometry parameters:
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32 | ** pmt double unchanged
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33 | ** eb double[3] unchanged
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34 | ** eh double[3] unchanged
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35 | ** em double unchanged
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36 | ** v double[3] unchanged
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37 | ** bm1 double unchanged
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38 | ** bpn double[3][3] unchanged
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39 | ** along double longitude + s' (radians)
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40 | ** xpl double polar motion xp wrt local meridian (radians)
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41 | ** ypl double polar motion yp wrt local meridian (radians)
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42 | ** sphi double sine of geodetic latitude
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43 | ** cphi double cosine of geodetic latitude
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44 | ** diurab double magnitude of diurnal aberration vector
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45 | ** eral double "local" Earth rotation angle (radians)
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46 | ** refa double refraction constant A (radians)
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47 | ** refb double refraction constant B (radians)
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48 | **
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49 | ** Returned (function value):
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50 | ** int status: +1 = dubious year (Note 2)
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51 | ** 0 = OK
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52 | ** -1 = unacceptable date
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53 | **
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54 | ** Notes:
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55 | **
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56 | ** 1) utc1+utc2 is quasi Julian Date (see Note 2), apportioned in any
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57 | ** convenient way between the two arguments, for example where utc1
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58 | ** is the Julian Day Number and utc2 is the fraction of a day.
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59 | **
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60 | ** However, JD cannot unambiguously represent UTC during a leap
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61 | ** second unless special measures are taken. The convention in the
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62 | ** present function is that the JD day represents UTC days whether
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63 | ** the length is 86399, 86400 or 86401 SI seconds.
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64 | **
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65 | ** Applications should use the function eraDtf2d to convert from
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66 | ** calendar date and time of day into 2-part quasi Julian Date, as
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67 | ** it implements the leap-second-ambiguity convention just
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68 | ** described.
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69 | **
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70 | ** 2) The warning status "dubious year" flags UTCs that predate the
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71 | ** introduction of the time scale or that are too far in the future
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72 | ** to be trusted. See eraDat for further details.
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73 | **
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74 | ** 3) UT1-UTC is tabulated in IERS bulletins. It increases by exactly
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75 | ** one second at the end of each positive UTC leap second,
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76 | ** introduced in order to keep UT1-UTC within +/- 0.9s. n.b. This
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77 | ** practice is under review, and in the future UT1-UTC may grow
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78 | ** essentially without limit.
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79 | **
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80 | ** 4) The geographical coordinates are with respect to the ERFA_WGS84
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81 | ** reference ellipsoid. TAKE CARE WITH THE LONGITUDE SIGN: the
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82 | ** longitude required by the present function is east-positive
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83 | ** (i.e. right-handed), in accordance with geographical convention.
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84 | **
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85 | ** 5) The polar motion xp,yp can be obtained from IERS bulletins. The
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86 | ** values are the coordinates (in radians) of the Celestial
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87 | ** Intermediate Pole with respect to the International Terrestrial
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88 | ** Reference System (see IERS Conventions 2003), measured along the
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89 | ** meridians 0 and 90 deg west respectively. For many applications,
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90 | ** xp and yp can be set to zero.
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91 | **
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92 | ** Internally, the polar motion is stored in a form rotated onto
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93 | ** the local meridian.
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94 | **
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95 | ** 6) If hm, the height above the ellipsoid of the observing station
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96 | ** in meters, is not known but phpa, the pressure in hPa (=mB), is
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97 | ** available, an adequate estimate of hm can be obtained from the
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98 | ** expression
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99 | **
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100 | ** hm = -29.3 * tsl * log ( phpa / 1013.25 );
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101 | **
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102 | ** where tsl is the approximate sea-level air temperature in K
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103 | ** (See Astrophysical Quantities, C.W.Allen, 3rd edition, section
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104 | ** 52). Similarly, if the pressure phpa is not known, it can be
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105 | ** estimated from the height of the observing station, hm, as
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106 | ** follows:
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107 | **
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108 | ** phpa = 1013.25 * exp ( -hm / ( 29.3 * tsl ) );
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109 | **
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110 | ** Note, however, that the refraction is nearly proportional to the
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111 | ** pressure and that an accurate phpa value is important for
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112 | ** precise work.
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113 | **
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114 | ** 7) The argument wl specifies the observing wavelength in
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115 | ** micrometers. The transition from optical to radio is assumed to
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116 | ** occur at 100 micrometers (about 3000 GHz).
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117 | **
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118 | ** 8) It is advisable to take great care with units, as even unlikely
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119 | ** values of the input parameters are accepted and processed in
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120 | ** accordance with the models used.
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121 | **
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122 | ** 9) In cases where the caller wishes to supply his own Earth
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123 | ** rotation information and refraction constants, the function
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124 | ** eraApc can be used instead of the present function.
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125 | **
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126 | ** 10) This is one of several functions that inserts into the astrom
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127 | ** structure star-independent parameters needed for the chain of
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128 | ** astrometric transformations ICRS <-> GCRS <-> CIRS <-> observed.
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129 | **
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130 | ** The various functions support different classes of observer and
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131 | ** portions of the transformation chain:
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132 | **
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133 | ** functions observer transformation
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134 | **
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135 | ** eraApcg eraApcg13 geocentric ICRS <-> GCRS
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136 | ** eraApci eraApci13 terrestrial ICRS <-> CIRS
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137 | ** eraApco eraApco13 terrestrial ICRS <-> observed
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138 | ** eraApcs eraApcs13 space ICRS <-> GCRS
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139 | ** eraAper eraAper13 terrestrial update Earth rotation
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140 | ** eraApio eraApio13 terrestrial CIRS <-> observed
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141 | **
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142 | ** Those with names ending in "13" use contemporary ERFA models to
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143 | ** compute the various ephemerides. The others accept ephemerides
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144 | ** supplied by the caller.
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145 | **
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146 | ** The transformation from ICRS to GCRS covers space motion,
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147 | ** parallax, light deflection, and aberration. From GCRS to CIRS
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148 | ** comprises frame bias and precession-nutation. From CIRS to
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149 | ** observed takes account of Earth rotation, polar motion, diurnal
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150 | ** aberration and parallax (unless subsumed into the ICRS <-> GCRS
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151 | ** transformation), and atmospheric refraction.
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152 | **
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153 | ** 11) The context structure astrom produced by this function is used
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154 | ** by eraAtioq and eraAtoiq.
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155 | **
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156 | ** Called:
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157 | ** eraUtctai UTC to TAI
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158 | ** eraTaitt TAI to TT
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159 | ** eraUtcut1 UTC to UT1
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160 | ** eraSp00 the TIO locator s', IERS 2000
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161 | ** eraEra00 Earth rotation angle, IAU 2000
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162 | ** eraRefco refraction constants for given ambient conditions
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163 | ** eraApio astrometry parameters, CIRS-observed
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164 | **
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165 | ** Copyright (C) 2013-2015, NumFOCUS Foundation.
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166 | ** Derived, with permission, from the SOFA library. See notes at end of file.
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167 | */
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168 | {
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169 | int j;
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170 | double tai1, tai2, tt1, tt2, ut11, ut12, sp, theta, refa, refb;
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171 |
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172 | /* UTC to other time scales. */
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173 | j = eraUtctai(utc1, utc2, &tai1, &tai2);
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174 | if ( j < 0 ) return -1;
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175 | j = eraTaitt(tai1, tai2, &tt1, &tt2);
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176 | j = eraUtcut1(utc1, utc2, dut1, &ut11, &ut12);
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177 | if ( j < 0 ) return -1;
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178 |
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179 | /* TIO locator s'. */
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180 | sp = eraSp00(tt1, tt2);
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181 |
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182 | /* Earth rotation angle. */
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183 | theta = eraEra00(ut11, ut12);
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184 |
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185 | /* Refraction constants A and B. */
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186 | eraRefco(phpa, tc, rh, wl, &refa, &refb);
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187 |
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188 | /* CIRS <-> observed astrometry parameters. */
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189 | eraApio(sp, theta, elong, phi, hm, xp, yp, refa, refb, astrom);
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190 |
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191 | /* Return any warning status. */
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192 | return j;
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193 |
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194 | /* Finished. */
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195 |
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196 | }
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197 | /*----------------------------------------------------------------------
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198 | **
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199 | **
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200 | ** Copyright (C) 2013-2015, NumFOCUS Foundation.
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201 | ** All rights reserved.
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202 | **
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203 | ** This library is derived, with permission, from the International
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204 | ** Astronomical Union's "Standards of Fundamental Astronomy" library,
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205 | ** available from http://www.iausofa.org.
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206 | **
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207 | ** The ERFA version is intended to retain identical functionality to
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208 | ** the SOFA library, but made distinct through different function and
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209 | ** file names, as set out in the SOFA license conditions. The SOFA
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210 | ** original has a role as a reference standard for the IAU and IERS,
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211 | ** and consequently redistribution is permitted only in its unaltered
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212 | ** state. The ERFA version is not subject to this restriction and
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213 | ** therefore can be included in distributions which do not support the
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214 | ** concept of "read only" software.
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215 | **
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216 | ** Although the intent is to replicate the SOFA API (other than
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217 | ** replacement of prefix names) and results (with the exception of
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218 | ** bugs; any that are discovered will be fixed), SOFA is not
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219 | ** responsible for any errors found in this version of the library.
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220 | **
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221 | ** If you wish to acknowledge the SOFA heritage, please acknowledge
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222 | ** that you are using a library derived from SOFA, rather than SOFA
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223 | ** itself.
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224 | **
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225 | **
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226 | ** TERMS AND CONDITIONS
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227 | **
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228 | ** Redistribution and use in source and binary forms, with or without
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229 | ** modification, are permitted provided that the following conditions
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230 | ** are met:
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231 | **
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232 | ** 1 Redistributions of source code must retain the above copyright
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233 | ** notice, this list of conditions and the following disclaimer.
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234 | **
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235 | ** 2 Redistributions in binary form must reproduce the above copyright
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236 | ** notice, this list of conditions and the following disclaimer in
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237 | ** the documentation and/or other materials provided with the
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238 | ** distribution.
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239 | **
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240 | ** 3 Neither the name of the Standards Of Fundamental Astronomy Board,
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241 | ** the International Astronomical Union nor the names of its
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242 | ** contributors may be used to endorse or promote products derived
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243 | ** from this software without specific prior written permission.
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244 | **
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245 | ** THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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246 | ** "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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247 | ** LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
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248 | ** FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
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249 | ** COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
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250 | ** INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
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251 | ** BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
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252 | ** LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
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253 | ** CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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254 | ** LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
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255 | ** ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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256 | ** POSSIBILITY OF SUCH DAMAGE.
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257 | **
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258 | */
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