File Coverage

erfasrc/src/atio13.c

Criterion	Covered	Total	%
statement	0	5	0.0
branch	0	2	0.0
condition			n/a
subroutine			n/a
pod			n/a
total	0	7	0.0

line	stmt	bran	code
1			#include "erfa.h"
2
3	0		int eraAtio13(double ri, double di,
4			double utc1, double utc2, double dut1,
5			double elong, double phi, double hm, double xp, double yp,
6			double phpa, double tc, double rh, double wl,
7			double aob, double zob, double *hob,
8			double dob, double rob)
9			/*
10			** - - - - - - - - - -
11			** e r a A t i o 1 3
12			** - - - - - - - - - -
13			**
14			** CIRS RA,Dec to observed place. The caller supplies UTC, site
15			** coordinates, ambient air conditions and observing wavelength.
16			**
17			** Given:
18			** ri double CIRS right ascension (CIO-based, radians)
19			** di double CIRS declination (radians)
20			** utc1 double UTC as a 2-part...
21			** utc2 double ...quasi Julian Date (Notes 1,2)
22			** dut1 double UT1-UTC (seconds, Note 3)
23			** elong double longitude (radians, east +ve, Note 4)
24			** phi double geodetic latitude (radians, Note 4)
25			** hm double height above ellipsoid (m, geodetic Notes 4,6)
26			** xp,yp double polar motion coordinates (radians, Note 5)
27			** phpa double pressure at the observer (hPa = mB, Note 6)
28			** tc double ambient temperature at the observer (deg C)
29			** rh double relative humidity at the observer (range 0-1)
30			** wl double wavelength (micrometers, Note 7)
31			**
32			** Returned:
33			** aob double* observed azimuth (radians: N=0,E=90)
34			** zob double* observed zenith distance (radians)
35			** hob double* observed hour angle (radians)
36			** dob double* observed declination (radians)
37			** rob double* observed right ascension (CIO-based, radians)
38			**
39			** Returned (function value):
40			** int status: +1 = dubious year (Note 2)
41			** 0 = OK
42			** -1 = unacceptable date
43			**
44			** Notes:
45			**
46			** 1) utc1+utc2 is quasi Julian Date (see Note 2), apportioned in any
47			** convenient way between the two arguments, for example where utc1
48			** is the Julian Day Number and utc2 is the fraction of a day.
49			**
50			** However, JD cannot unambiguously represent UTC during a leap
51			** second unless special measures are taken. The convention in the
52			** present function is that the JD day represents UTC days whether
53			** the length is 86399, 86400 or 86401 SI seconds.
54			**
55			** Applications should use the function eraDtf2d to convert from
56			** calendar date and time of day into 2-part quasi Julian Date, as
57			** it implements the leap-second-ambiguity convention just
58			** described.
59			**
60			** 2) The warning status "dubious year" flags UTCs that predate the
61			** introduction of the time scale or that are too far in the
62			** future to be trusted. See eraDat for further details.
63			**
64			** 3) UT1-UTC is tabulated in IERS bulletins. It increases by exactly
65			** one second at the end of each positive UTC leap second,
66			** introduced in order to keep UT1-UTC within +/- 0.9s. n.b. This
67			** practice is under review, and in the future UT1-UTC may grow
68			** essentially without limit.
69			**
70			** 4) The geographical coordinates are with respect to the ERFA_WGS84
71			** reference ellipsoid. TAKE CARE WITH THE LONGITUDE SIGN: the
72			** longitude required by the present function is east-positive
73			** (i.e. right-handed), in accordance with geographical convention.
74			**
75			** 5) The polar motion xp,yp can be obtained from IERS bulletins. The
76			** values are the coordinates (in radians) of the Celestial
77			** Intermediate Pole with respect to the International Terrestrial
78			** Reference System (see IERS Conventions 2003), measured along the
79			** meridians 0 and 90 deg west respectively. For many
80			** applications, xp and yp can be set to zero.
81			**
82			** 6) If hm, the height above the ellipsoid of the observing station
83			** in meters, is not known but phpa, the pressure in hPa (=mB), is
84			** available, an adequate estimate of hm can be obtained from the
85			** expression
86			**
87			** hm = -29.3 * tsl * log ( phpa / 1013.25 );
88			**
89			** where tsl is the approximate sea-level air temperature in K
90			** (See Astrophysical Quantities, C.W.Allen, 3rd edition, section
91			** 52). Similarly, if the pressure phpa is not known, it can be
92			** estimated from the height of the observing station, hm, as
93			** follows:
94			**
95			** phpa = 1013.25 * exp ( -hm / ( 29.3 * tsl ) );
96			**
97			** Note, however, that the refraction is nearly proportional to
98			** the pressure and that an accurate phpa value is important for
99			** precise work.
100			**
101			** 7) The argument wl specifies the observing wavelength in
102			** micrometers. The transition from optical to radio is assumed to
103			** occur at 100 micrometers (about 3000 GHz).
104			**
105			** 8) "Observed" Az,ZD means the position that would be seen by a
106			** perfect geodetically aligned theodolite. (Zenith distance is
107			** used rather than altitude in order to reflect the fact that no
108			** allowance is made for depression of the horizon.) This is
109			** related to the observed HA,Dec via the standard rotation, using
110			** the geodetic latitude (corrected for polar motion), while the
111			** observed HA and RA are related simply through the Earth rotation
112			** angle and the site longitude. "Observed" RA,Dec or HA,Dec thus
113			** means the position that would be seen by a perfect equatorial
114			** with its polar axis aligned to the Earth's axis of rotation.
115			**
116			** 9) The accuracy of the result is limited by the corrections for
117			** refraction, which use a simple Atan(z) + Btan^3(z) model.
118			** Providing the meteorological parameters are known accurately and
119			** there are no gross local effects, the predicted astrometric
120			** coordinates should be within 0.05 arcsec (optical) or 1 arcsec
121			** (radio) for a zenith distance of less than 70 degrees, better
122			** than 30 arcsec (optical or radio) at 85 degrees and better
123			** than 20 arcmin (optical) or 30 arcmin (radio) at the horizon.
124			**
125			** 10) The complementary functions eraAtio13 and eraAtoi13 are self-
126			** consistent to better than 1 microarcsecond all over the
127			** celestial sphere.
128			**
129			** 11) It is advisable to take great care with units, as even unlikely
130			** values of the input parameters are accepted and processed in
131			** accordance with the models used.
132			**
133			** Called:
134			** eraApio13 astrometry parameters, CIRS-observed, 2013
135			** eraAtioq quick CIRS to observed
136			**
137			** Copyright (C) 2013-2019, NumFOCUS Foundation.
138			** Derived, with permission, from the SOFA library. See notes at end of file.
139			*/
140			{
141			int j;
142			eraASTROM astrom;
143
144
145			/* Star-independent astrometry parameters for CIRS->observed. */
146	0		j = eraApio13(utc1, utc2, dut1, elong, phi, hm, xp, yp,
147			phpa, tc, rh, wl, &astrom);
148
149			/* Abort if bad UTC. */
150	0	0	if ( j < 0 ) return j;
151
152			/* Transform CIRS to observed. */
153	0		eraAtioq(ri, di, &astrom, aob, zob, hob, dob, rob);
154
155			/* Return OK/warning status. */
156	0		return j;
157
158			/* Finished. */
159
160			}
161			/*----------------------------------------------------------------------
162			**
163			**
164			** Copyright (C) 2013-2019, NumFOCUS Foundation.
165			** All rights reserved.
166			**
167			** This library is derived, with permission, from the International
168			** Astronomical Union's "Standards of Fundamental Astronomy" library,
169			** available from http://www.iausofa.org.
170			**
171			** The ERFA version is intended to retain identical functionality to
172			** the SOFA library, but made distinct through different function and
173			** file names, as set out in the SOFA license conditions. The SOFA
174			** original has a role as a reference standard for the IAU and IERS,
175			** and consequently redistribution is permitted only in its unaltered
176			** state. The ERFA version is not subject to this restriction and
177			** therefore can be included in distributions which do not support the
178			** concept of "read only" software.
179			**
180			** Although the intent is to replicate the SOFA API (other than
181			** replacement of prefix names) and results (with the exception of
182			** bugs; any that are discovered will be fixed), SOFA is not
183			** responsible for any errors found in this version of the library.
184			**
185			** If you wish to acknowledge the SOFA heritage, please acknowledge
186			** that you are using a library derived from SOFA, rather than SOFA
187			** itself.
188			**
189			**
190			** TERMS AND CONDITIONS
191			**
192			** Redistribution and use in source and binary forms, with or without
193			** modification, are permitted provided that the following conditions
194			** are met:
195			**
196			** 1 Redistributions of source code must retain the above copyright
197			** notice, this list of conditions and the following disclaimer.
198			**
199			** 2 Redistributions in binary form must reproduce the above copyright
200			** notice, this list of conditions and the following disclaimer in
201			** the documentation and/or other materials provided with the
202			** distribution.
203			**
204			** 3 Neither the name of the Standards Of Fundamental Astronomy Board,
205			** the International Astronomical Union nor the names of its
206			** contributors may be used to endorse or promote products derived
207			** from this software without specific prior written permission.
208			**
209			** THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
210			** "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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