File Coverage

palsrc/palFk524.c
Criterion Covered Total %
statement 0 56 0.0
branch 0 12 0.0
condition n/a
subroutine n/a
pod n/a
total 0 68 0.0


line stmt bran cond sub pod time code
1             /*
2             *+
3             * Name:
4             * palFk524
5              
6             * Purpose:
7             * Convert J2000.0 FK5 star data to B1950.0 FK4.
8              
9             * Language:
10             * Starlink ANSI C
11              
12             * Type of Module:
13             * Library routine
14              
15             * Invocation:
16             * palFk524( double r2000, double d2000, double dr2000, double dd2000,
17             * double p2000, double v2000, double *r1950, double *d1950,
18             * double *dr1950, double *dd1950, double *p1950, double *v1950 )
19              
20             * Arguments:
21             * r2000 = double (Given)
22             * J2000.0 FK5 RA (radians).
23             * d2000 = double (Given)
24             * J2000.0 FK5 Dec (radians).
25             * dr2000 = double (Given)
26             * J2000.0 FK5 RA proper motion (rad/Jul.yr)
27             * dd2000 = double (Given)
28             * J2000.0 FK5 Dec proper motion (rad/Jul.yr)
29             * p2000 = double (Given)
30             * J2000.0 FK5 parallax (arcsec)
31             * v2000 = double (Given)
32             * J2000.0 FK5 radial velocity (km/s, +ve = moving away)
33             * r1950 = double * (Returned)
34             * B1950.0 FK4 RA (radians).
35             * d1950 = double * (Returned)
36             * B1950.0 FK4 Dec (radians).
37             * dr1950 = double * (Returned)
38             * B1950.0 FK4 RA proper motion (rad/Jul.yr)
39             * dd1950 = double * (Returned)
40             * B1950.0 FK4 Dec proper motion (rad/Jul.yr)
41             * p1950 = double * (Returned)
42             * B1950.0 FK4 parallax (arcsec)
43             * v1950 = double * (Returned)
44             * B1950.0 FK4 radial velocity (km/s, +ve = moving away)
45              
46             * Description:
47             * This function converts stars from the IAU 1976, FK5, Fricke
48             * system, to the Bessel-Newcomb, FK4 system. The precepts
49             * of Smith et al (Ref 1) are followed, using the implementation
50             * by Yallop et al (Ref 2) of a matrix method due to Standish.
51             * Kinoshita's development of Andoyer's post-Newcomb precession is
52             * used. The numerical constants from Seidelmann et al (Ref 3) are
53             * used canonically.
54              
55             * Notes:
56             * - The proper motions in RA are dRA/dt rather than
57             * cos(Dec)*dRA/dt, and are per year rather than per century.
58             * - Note that conversion from Julian epoch 2000.0 to Besselian
59             * epoch 1950.0 only is provided for. Conversions involving
60             * other epochs will require use of the appropriate precession,
61             * proper motion, and E-terms routines before and/or after
62             * FK524 is called.
63             * - In the FK4 catalogue the proper motions of stars within
64             * 10 degrees of the poles do not embody the differential
65             * E-term effect and should, strictly speaking, be handled
66             * in a different manner from stars outside these regions.
67             * However, given the general lack of homogeneity of the star
68             * data available for routine astrometry, the difficulties of
69             * handling positions that may have been determined from
70             * astrometric fields spanning the polar and non-polar regions,
71             * the likelihood that the differential E-terms effect was not
72             * taken into account when allowing for proper motion in past
73             * astrometry, and the undesirability of a discontinuity in
74             * the algorithm, the decision has been made in this routine to
75             * include the effect of differential E-terms on the proper
76             * motions for all stars, whether polar or not. At epoch 2000,
77             * and measuring on the sky rather than in terms of dRA, the
78             * errors resulting from this simplification are less than
79             * 1 milliarcsecond in position and 1 milliarcsecond per
80             * century in proper motion.
81             *
82             * References:
83             * - Smith, C.A. et al, 1989. "The transformation of astrometric
84             * catalog systems to the equinox J2000.0". Astron.J. 97, 265.
85             * - Yallop, B.D. et al, 1989. "Transformation of mean star places
86             * from FK4 B1950.0 to FK5 J2000.0 using matrices in 6-space".
87             * Astron.J. 97, 274.
88             * - Seidelmann, P.K. (ed), 1992. "Explanatory Supplement to
89             * the Astronomical Almanac", ISBN 0-935702-68-7.
90              
91             * Authors:
92             * PTW: Pat Wallace (STFC)
93             * DSB: David Berry (JAC, Hawaii)
94             * {enter_new_authors_here}
95              
96             * History:
97             * 2012-02-13 (DSB):
98             * Initial version with documentation taken from Fortran SLA
99             * Adapted with permission from the Fortran SLALIB library.
100             * {enter_further_changes_here}
101              
102             * Copyright:
103             * Copyright (C) 1995 Rutherford Appleton Laboratory
104             * Copyright (C) 2012 Science and Technology Facilities Council.
105             * All Rights Reserved.
106              
107             * Licence:
108             * This program is free software: you can redistribute it and/or
109             * modify it under the terms of the GNU Lesser General Public
110             * License as published by the Free Software Foundation, either
111             * version 3 of the License, or (at your option) any later
112             * version.
113             *
114             * This program is distributed in the hope that it will be useful,
115             * but WITHOUT ANY WARRANTY; without even the implied warranty of
116             * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
117             * GNU Lesser General Public License for more details.
118             *
119             * You should have received a copy of the GNU Lesser General
120             * License along with this program. If not, see
121             * .
122              
123             * Bugs:
124             * {note_any_bugs_here}
125             *-
126             */
127              
128             #include "pal.h"
129             #include "palmac.h"
130             #include "math.h"
131              
132 0           void palFk524( double r2000, double d2000, double dr2000, double dd2000,
133             double p2000, double v2000, double *r1950, double *d1950,
134             double *dr1950, double *dd1950, double *p1950, double *v1950 ){
135              
136             /* Local Variables; */
137             double r, d, ur, ud, px, rv;
138             double sr, cr, sd, cd, x, y, z, w;
139             double v1[ 6 ], v2[ 6 ];
140             double xd, yd, zd;
141             double rxyz, wd, rxysq, rxy;
142             int i, j;
143              
144             /* Small number to avoid arithmetic problems. */
145             static const double tiny = 1.0E-30;
146              
147             /* Canonical constants (see references). Constant vector and matrix. */
148             double a[ 6 ] = { -1.62557E-6, -0.31919E-6, -0.13843E-6,
149             +1.245E-3, -1.580E-3, -0.659E-3 };
150 0           double emi[ 6 ][ 6 ] = {
151             { 0.9999256795, 0.0111814828, 0.0048590039,
152             -0.00000242389840, -0.00000002710544, -0.00000001177742},
153             {-0.0111814828, 0.9999374849, -0.0000271771,
154             0.00000002710544, -0.00000242392702, 0.00000000006585 },
155             {-0.0048590040, -0.0000271557, 0.9999881946,
156             0.00000001177742, 0.00000000006585, -0.00000242404995 },
157             {-0.000551, 0.238509, -0.435614,
158             0.99990432, 0.01118145, 0.00485852 },
159             {-0.238560, -0.002667, 0.012254,
160             -0.01118145, 0.99991613, -0.00002717},
161             { 0.435730, -0.008541, 0.002117,
162             -0.00485852, -0.00002716, 0.99996684 } };
163              
164             /* Pick up J2000 data (units radians and arcsec/JC). */
165             r = r2000;
166             d = d2000;
167 0           ur = dr2000*PAL__PMF;
168 0           ud = dd2000*PAL__PMF;
169             px = p2000;
170             rv = v2000;
171              
172             /* Spherical to Cartesian. */
173 0           sr = sin( r );
174 0           cr = cos( r );
175 0           sd = sin( d );
176 0           cd = cos( d );
177              
178 0           x = cr*cd;
179 0           y = sr*cd;
180             z = sd;
181              
182 0           w = PAL__VF*rv*px;
183              
184 0           v1[ 0 ] = x;
185 0           v1[ 1 ] = y;
186 0           v1[ 2 ] = z;
187              
188 0           v1[ 3 ] = -ur*y - cr*sd*ud + w*x;
189 0           v1[ 4 ] = ur*x - sr*sd*ud + w*y;
190 0           v1[ 5 ] = cd*ud + w*z;
191              
192             /* Convert position+velocity vector to BN system. */
193 0 0         for( i = 0; i < 6; i++ ) {
194             w = 0.0;
195 0 0         for( j = 0; j < 6; j++ ) {
196 0           w += emi[ i ][ j ]*v1[ j ];
197             }
198 0           v2[ i ] = w;
199             }
200              
201             /* Position vector components and magnitude. */
202 0           x = v2[ 0 ];
203 0           y = v2[ 1 ];
204 0           z = v2[ 2 ];
205 0           rxyz = sqrt( x*x + y*y + z*z );
206              
207             /* Apply E-terms to position. */
208 0           w = x*a[ 0 ] + y*a[ 1 ] + z*a[ 2 ];
209 0           x += a[ 0 ]*rxyz - w*x;
210 0           y += a[ 1 ]*rxyz - w*y;
211 0           z += a[ 2 ]*rxyz - w*z;
212              
213             /* Recompute magnitude. */
214 0           rxyz = sqrt( x*x + y*y + z*z );
215              
216             /* Apply E-terms to both position and velocity. */
217             x = v2[ 0 ];
218             y = v2[ 1 ];
219             z = v2[ 2 ];
220             w = x*a[ 0 ] + y*a[ 1 ] + z*a[ 2 ];
221 0           wd = x*a[ 3 ] + y*a[ 4 ] + z*a[ 5 ];
222 0           x += a[ 0 ]*rxyz - w*x;
223 0           y += a[ 1 ]*rxyz - w*y;
224 0           z += a[ 2 ]*rxyz - w*z;
225 0           xd = v2[ 3 ] + a[ 3 ]*rxyz - wd*x;
226 0           yd = v2[ 4 ] + a[ 4 ]*rxyz - wd*y;
227 0           zd = v2[ 5 ] + a[ 5 ]*rxyz - wd*z;
228              
229             /* Convert to spherical. */
230 0           rxysq = x*x + y*y;
231 0           rxy = sqrt( rxysq );
232              
233 0 0         if( x == 0.0 && y == 0.0 ) {
234             r = 0.0;
235             } else {
236 0           r = atan2( y, x );
237 0 0         if( r < 0.0 ) r += PAL__D2PI;
238             }
239 0           d = atan2( z, rxy );
240              
241 0 0         if( rxy > tiny ) {
242 0           ur = ( x*yd - y*xd )/rxysq;
243 0           ud = ( zd*rxysq - z*( x*xd + y*yd ) )/( ( rxysq + z*z )*rxy );
244             }
245              
246             /* Radial velocity and parallax. */
247 0 0         if( px > tiny ) {
248 0           rv = ( x*xd + y*yd + z*zd )/( px*PAL__VF*rxyz );
249 0           px /= rxyz;
250             }
251              
252             /* Return results. */
253 0           *r1950 = r;
254 0           *d1950 = d;
255 0           *dr1950 = ur/PAL__PMF;
256 0           *dd1950 = ud/PAL__PMF;
257 0           *p1950 = px;
258 0           *v1950 = rv;
259 0           }