source: trunk/FACT++/erfa/src/pvstar.c@ 18679

#include "erfa.h"

int eraPvstar(double pv[2][3], double *ra, double *dec,
              double *pmr, double *pmd, double *px, double *rv)
/*
**  - - - - - - - - - -
**   e r a P v s t a r
**  - - - - - - - - - -
**
**  Convert star position+velocity vector to catalog coordinates.
**
**  Given (Note 1):
**     pv     double[2][3]   pv-vector (AU, AU/day)
**
**  Returned (Note 2):
**     ra     double         right ascension (radians)
**     dec    double         declination (radians)
**     pmr    double         RA proper motion (radians/year)
**     pmd    double         Dec proper motion (radians/year)
**     px     double         parallax (arcsec)
**     rv     double         radial velocity (km/s, positive = receding)
**
**  Returned (function value):
**            int            status:
**                              0 = OK
**                             -1 = superluminal speed (Note 5)
**                             -2 = null position vector
**
**  Notes:
**
**  1) The specified pv-vector is the coordinate direction (and its rate
**     of change) for the date at which the light leaving the star
**     reached the solar-system barycenter.
**
**  2) The star data returned by this function are "observables" for an
**     imaginary observer at the solar-system barycenter.  Proper motion
**     and radial velocity are, strictly, in terms of barycentric
**     coordinate time, TCB.  For most practical applications, it is
**     permissible to neglect the distinction between TCB and ordinary
**     "proper" time on Earth (TT/TAI).  The result will, as a rule, be
**     limited by the intrinsic accuracy of the proper-motion and
**     radial-velocity data;  moreover, the supplied pv-vector is likely
**     to be merely an intermediate result (for example generated by the
**     function eraStarpv), so that a change of time unit will cancel
**     out overall.
**
**     In accordance with normal star-catalog conventions, the object's
**     right ascension and declination are freed from the effects of
**     secular aberration.  The frame, which is aligned to the catalog
**     equator and equinox, is Lorentzian and centered on the SSB.
**
**     Summarizing, the specified pv-vector is for most stars almost
**     identical to the result of applying the standard geometrical
**     "space motion" transformation to the catalog data.  The
**     differences, which are the subject of the Stumpff paper cited
**     below, are:
**
**     (i) In stars with significant radial velocity and proper motion,
**     the constantly changing light-time distorts the apparent proper
**     motion.  Note that this is a classical, not a relativistic,
**     effect.
**
**     (ii) The transformation complies with special relativity.
**
**  3) Care is needed with units.  The star coordinates are in radians
**     and the proper motions in radians per Julian year, but the
**     parallax is in arcseconds; the radial velocity is in km/s, but
**     the pv-vector result is in AU and AU/day.
**
**  4) The proper motions are the rate of change of the right ascension
**     and declination at the catalog epoch and are in radians per Julian
**     year.  The RA proper motion is in terms of coordinate angle, not
**     true angle, and will thus be numerically larger at high
**     declinations.
**
**  5) Straight-line motion at constant speed in the inertial frame is
**     assumed.  If the speed is greater than or equal to the speed of
**     light, the function aborts with an error status.
**
**  6) The inverse transformation is performed by the function eraStarpv.
**
**  Called:
**     eraPn        decompose p-vector into modulus and direction
**     eraPdp       scalar product of two p-vectors
**     eraSxp       multiply p-vector by scalar
**     eraPmp       p-vector minus p-vector
**     eraPm        modulus of p-vector
**     eraPpp       p-vector plus p-vector
**     eraPv2s      pv-vector to spherical
**     eraAnp       normalize angle into range 0 to 2pi
**
**  Reference:
**
**     Stumpff, P., 1985, Astron.Astrophys. 144, 232-240.
**
**  Copyright (C) 2013-2015, NumFOCUS Foundation.
**  Derived, with permission, from the SOFA library.  See notes at end of file.
*/
{
   double r, x[3], vr, ur[3], vt, ut[3], bett, betr, d, w, del,
          usr[3], ust[3], a, rad, decd, rd;

/* Isolate the radial component of the velocity (AU/day, inertial). */
   eraPn(pv[0], &r, x);
   vr = eraPdp(x, pv[1]);
   eraSxp(vr, x, ur);

/* Isolate the transverse component of the velocity (AU/day, inertial). */
   eraPmp(pv[1], ur, ut);
   vt = eraPm(ut);

/* Special-relativity dimensionless parameters. */
   bett = vt / ERFA_DC;
   betr = vr / ERFA_DC;

/* The inertial-to-observed correction terms. */
   d = 1.0 + betr;
   w = 1.0 - betr*betr - bett*bett;
   if (d == 0.0 || w < 0) return -1;
   del = sqrt(w) - 1.0;

/* Apply relativistic correction factor to radial velocity component. */
   w = (betr != 0) ? (betr - del) / (betr * d) : 1.0;
   eraSxp(w, ur, usr);

/* Apply relativistic correction factor to tangential velocity */
/* component.                                                  */
   eraSxp(1.0/d, ut, ust);

/* Combine the two to obtain the observed velocity vector (AU/day). */
   eraPpp(usr, ust, pv[1]);

/* Cartesian to spherical. */
   eraPv2s(pv, &a, dec, &r, &rad, &decd, &rd);
   if (r == 0.0) return -2;

/* Return RA in range 0 to 2pi. */
   *ra = eraAnp(a);

/* Return proper motions in radians per year. */
   *pmr = rad * ERFA_DJY;
   *pmd = decd * ERFA_DJY;

/* Return parallax in arcsec. */
   *px = ERFA_DR2AS / r;

/* Return radial velocity in km/s. */
   *rv = 1e-3 * rd * ERFA_DAU / ERFA_DAYSEC;

/* OK status. */
   return 0;

}
/*----------------------------------------------------------------------
**  
**  
**  Copyright (C) 2013-2015, NumFOCUS Foundation.
**  All rights reserved.
**  
**  This library is derived, with permission, from the International
**  Astronomical Union's "Standards of Fundamental Astronomy" library,
**  available from http://www.iausofa.org.
**  
**  The ERFA version is intended to retain identical functionality to
**  the SOFA library, but made distinct through different function and
**  file names, as set out in the SOFA license conditions.  The SOFA
**  original has a role as a reference standard for the IAU and IERS,
**  and consequently redistribution is permitted only in its unaltered
**  state.  The ERFA version is not subject to this restriction and
**  therefore can be included in distributions which do not support the
**  concept of "read only" software.
**  
**  Although the intent is to replicate the SOFA API (other than
**  replacement of prefix names) and results (with the exception of
**  bugs;  any that are discovered will be fixed), SOFA is not
**  responsible for any errors found in this version of the library.
**  
**  If you wish to acknowledge the SOFA heritage, please acknowledge
**  that you are using a library derived from SOFA, rather than SOFA
**  itself.
**  
**  
**  TERMS AND CONDITIONS
**  
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**  modification, are permitted provided that the following conditions
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**  
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