Exemple #1
0
   void sxform_c ( ConstSpiceChar  * from, 
                   ConstSpiceChar  * to, 
                   SpiceDouble       et, 
                   SpiceDouble       xform[6][6] ) 
/*

-Brief_I/O
 
   VARIABLE  I/O  DESCRIPTION 
   --------  ---  -------------------------------------------------- 
   from       I   Name of the frame to transform from.
   to         I   Name of the frame to transform to.
   et         I   Epoch of the state transformation matrix.
   xform      O   A state transformation matrix.
 
-Detailed_Input
 
   from        is the name of a reference frame in which a state is
               known.
 
   to          is the name of a reference frame in which it is desired
               to represent the state.
 
   et          is the epoch in ephemeris seconds past the epoch of
               J2000 (TDB) at which the state transformation matrix
               should be evaluated.

-Detailed_Output
 
   xform       is the matrix that transforms states from the reference
               frame `from' to the frame `to' at epoch `et'. If (x, y,
               z, dx, dy, dz) is a state relative to the frame `from'
               then the vector ( x', y', z', dx', dy', dz' ) is the
               same state relative to the frame `to' at epoch `et'.
               Here the vector ( x', y', z', dx', dy', dz' ) is defined
               by the equation:
 
                  -   -       -          -     -  - 
                 | x'  |     |            |   | x  | 
                 | y'  |     |            |   | y  | 
                 | z'  |  =  |   xform    |   | z  | 
                 | dx' |     |            |   | dx | 
                 | dy' |     |            |   | dy | 
                 | dz' |     |            |   | dz | 
                  -   -       -          -     -  - 
 
-Parameters
 
   None. 
 
-Exceptions
 
   1) If sufficient information has not been supplied via loaded 
      SPICE kernels to compute the transformation between the 
      two frames, the error will be diagnosed by a routine 
      in the call tree of this routine. 
 
   2) If either frame `from' or `to' is not recognized the error 
      SPICE(UNKNOWNFRAME) will be signaled. 
 
-Files
 
   None. 
 
-Particulars
 
   This routine provides the user level interface for computing 
   state transformations from one reference frame to another. 
 
   Note that the reference frames may be inertial or non-inertial. 
   However, the user must take care that sufficient SPICE kernel 
   information is loaded to provide a complete state transformation 
   path from the `from' frame to the `to' frame. 
 
-Examples
 
   Suppose that you have geodetic coordinates of a station on 
   the surface of the earth and that you need the inertial 
   (J2000) state of this station.  The following code fragment 
   illustrates how to transform the position of the station to 
   a J2000 state. 
 
      #include "SpiceUsr.h"
          .
          .
          .
      bodvcd_c ( 399, radii, 3, &n, abc  ); 
 
      equatr   =  abc[0]; 
      polar    =  abc[2]; 
      f        = (equatr - polar) / equatr; 
 
      georec_c ( long, lat, 0.0,  equatr, f,  estate ); 
 
      estate[3] = 0.0; 
      estate[4] = 0.0; 
      estate[5] = 0.0; 
 
      sxform_c ( "IAU_EARTH", "J2000",   et,    xform  ); 
      mxvg_c   (  xform,       estate,   6,  6, jstate ); 
 
   The state `jstate' is the desired J2000 state of the station. 
 
 
-Restrictions
 
   None. 
 
-Literature_References
 
    None. 
 
-Author_and_Institution
 
   C.H. Acton      (JPL)
   N.J. Bachman    (JPL)
   B.V. Semenov    (JPL)
   W.L. Taber      (JPL) 
 
-Version
 
   -CSPICE Version 1.1.3, 27-FEB-2008 (BVS)

       Added FRAMES to the Required_Reading section of the header.

   -CSPICE Version 1.1.2, 24-OCT-2005 (NJB)

       Header updates: example had invalid flattening factor
       computation; this was corrected.  Reference to bodvar_c was
       replaced with reference to bodvcd_c.

   -CSPICE Version 1.1.1, 03-JUL-2003 (NJB) (CHA)

       Various header corrections were made.
   
   -CSPICE Version 1.1.0, 08-FEB-1998 (NJB)  
   
       References to C2F_CreateStr_Sig were removed; code was
       cleaned up accordingly.  String checks are now done using
       the macro CHKFSTR.
       
   -CSPICE Version 1.0.0, 25-OCT-1997 (NJB)
   
      Based on SPICELIB Version 1.0.0, 19-SEP-1995 (WLT)

-Index_Entries
 
   Find a state transformation matrix 
 
-&
*/

{ /* Begin sxform_c */

   /*
   Participate in error tracing.
   */
   chkin_c ( "sxform_c");
   

   /*
   Check the input strings to make sure the pointers are non-null 
   and the string lengths are non-zero.
   */
   CHKFSTR ( CHK_STANDARD, "sxform_c", from );
   CHKFSTR ( CHK_STANDARD, "sxform_c", to   );

   
   /*
   Get the desired matrix from sxform_.
   */
   sxform_ (  ( char           * ) from,
              ( char           * ) to,
              ( doublereal     * ) &et,
              ( doublereal     * ) xform,
              ( ftnlen           ) strlen(from),
              ( ftnlen           ) strlen(to)    );

   /*
   Transpose the matrix on output.
   */ 
   xpose6_c ( xform, xform );
   
   
   chkout_c ( "sxform_c");

} /* End sxform_c */
Exemple #2
0
/* $Procedure      ZZGFSSOB ( GF, state of sub-observer point ) */
/* Subroutine */ int zzgfssob_(char *method, integer *trgid, doublereal *et, 
	char *fixref, char *abcorr, integer *obsid, doublereal *radii, 
	doublereal *state, ftnlen method_len, ftnlen fixref_len, ftnlen 
	abcorr_len)
{
    /* Initialized data */

    static logical first = TRUE_;
    static integer prvobs = 0;
    static integer prvtrg = 0;
    static char svobs[36] = "                                    ";
    static char svtarg[36] = "                                    ";

    /* System generated locals */
    integer i__1;

    /* Builtin functions */
    integer s_rnge(char *, integer, char *, integer);

    /* Local variables */
    doublereal dalt[2];
    logical near__, geom;
    extern /* Subroutine */ int vhat_(doublereal *, doublereal *), vscl_(
	    doublereal *, doublereal *, doublereal *);
    extern doublereal vdot_(doublereal *, doublereal *);
    logical xmit;
    extern /* Subroutine */ int mxvg_(doublereal *, doublereal *, integer *, 
	    integer *, doublereal *);
    doublereal upos[3];
    extern /* Subroutine */ int zzstelab_(logical *, doublereal *, doublereal 
	    *, doublereal *, doublereal *, doublereal *), zzcorsxf_(logical *,
	     doublereal *, doublereal *, doublereal *);
    integer i__;
    extern /* Subroutine */ int zzprscor_(char *, logical *, ftnlen);
    doublereal t;
    extern /* Subroutine */ int vaddg_(doublereal *, doublereal *, integer *, 
	    doublereal *);
    doublereal scale;
    extern /* Subroutine */ int chkin_(char *, ftnlen), errch_(char *, char *,
	     ftnlen, ftnlen);
    doublereal savel[3];
    logical found;
    extern /* Subroutine */ int moved_(doublereal *, integer *, doublereal *),
	     vsubg_(doublereal *, doublereal *, integer *, doublereal *);
    doublereal stemp[6];
    extern logical eqstr_(char *, char *, ftnlen, ftnlen);
    doublereal xform[36]	/* was [6][6] */;
    logical uselt;
    extern /* Subroutine */ int bodc2s_(integer *, char *, ftnlen);
    doublereal ssbtg0[6];
    extern logical failed_(void);
    doublereal sa[3];
    extern /* Subroutine */ int cleard_(integer *, doublereal *);
    doublereal lt;
    integer frcode;
    extern doublereal clight_(void);
    extern logical return_(void);
    doublereal corxfi[36]	/* was [6][6] */, corxfm[36]	/* was [6][6] 
	    */, fxosta[6], fxpsta[6], fxpvel[3], fxtsta[6], obspnt[6], obssta[
	    12]	/* was [6][2] */, obstrg[6], acc[3], pntsta[6], raysta[6], 
	    sastat[6], spoint[3], srfvec[3], ssbobs[6], ssbtrg[6], trgepc;
    integer center, clssid, frclss;
    logical attblk[6], usestl;
    extern /* Subroutine */ int setmsg_(char *, ftnlen);
    logical fnd;
    extern /* Subroutine */ int sigerr_(char *, ftnlen), chkout_(char *, 
	    ftnlen), namfrm_(char *, integer *, ftnlen), frinfo_(integer *, 
	    integer *, integer *, integer *, logical *), errint_(char *, 
	    integer *, ftnlen), spkgeo_(integer *, doublereal *, char *, 
	    integer *, doublereal *, doublereal *, ftnlen), vminug_(
	    doublereal *, integer *, doublereal *), dnearp_(doublereal *, 
	    doublereal *, doublereal *, doublereal *, doublereal *, 
	    doublereal *, logical *), surfpv_(doublereal *, doublereal *, 
	    doublereal *, doublereal *, doublereal *, doublereal *, logical *)
	    , subpnt_(char *, char *, doublereal *, char *, char *, char *, 
	    doublereal *, doublereal *, doublereal *, ftnlen, ftnlen, ftnlen, 
	    ftnlen, ftnlen), spkssb_(integer *, doublereal *, char *, 
	    doublereal *, ftnlen);
    doublereal dlt;
    extern /* Subroutine */ int sxform_(char *, char *, doublereal *, 
	    doublereal *, ftnlen, ftnlen), qderiv_(integer *, doublereal *, 
	    doublereal *, doublereal *, doublereal *), invstm_(doublereal *, 
	    doublereal *);

/* $ Abstract */

/*     SPICE private routine intended solely for the support of SPICE */
/*     routines. Users should not call this routine directly due to the */
/*     volatile nature of this routine. */

/*     Return the state of a sub-observer point used to define */
/*     coordinates referenced in a GF search. */

/* $ Disclaimer */

/*     THIS SOFTWARE AND ANY RELATED MATERIALS WERE CREATED BY THE */
/*     CALIFORNIA INSTITUTE OF TECHNOLOGY (CALTECH) UNDER A U.S. */
/*     GOVERNMENT CONTRACT WITH THE NATIONAL AERONAUTICS AND SPACE */
/*     ADMINISTRATION (NASA). THE SOFTWARE IS TECHNOLOGY AND SOFTWARE */
/*     PUBLICLY AVAILABLE UNDER U.S. EXPORT LAWS AND IS PROVIDED "AS-IS" */
/*     TO THE RECIPIENT WITHOUT WARRANTY OF ANY KIND, INCLUDING ANY */
/*     WARRANTIES OF PERFORMANCE OR MERCHANTABILITY OR FITNESS FOR A */
/*     PARTICULAR USE OR PURPOSE (AS SET FORTH IN UNITED STATES UCC */
/*     SECTIONS 2312-2313) OR FOR ANY PURPOSE WHATSOEVER, FOR THE */
/*     SOFTWARE AND RELATED MATERIALS, HOWEVER USED. */

/*     IN NO EVENT SHALL CALTECH, ITS JET PROPULSION LABORATORY, OR NASA */
/*     BE LIABLE FOR ANY DAMAGES AND/OR COSTS, INCLUDING, BUT NOT */
/*     LIMITED TO, INCIDENTAL OR CONSEQUENTIAL DAMAGES OF ANY KIND, */
/*     INCLUDING ECONOMIC DAMAGE OR INJURY TO PROPERTY AND LOST PROFITS, */
/*     REGARDLESS OF WHETHER CALTECH, JPL, OR NASA BE ADVISED, HAVE */
/*     REASON TO KNOW, OR, IN FACT, SHALL KNOW OF THE POSSIBILITY. */

/*     RECIPIENT BEARS ALL RISK RELATING TO QUALITY AND PERFORMANCE OF */
/*     THE SOFTWARE AND ANY RELATED MATERIALS, AND AGREES TO INDEMNIFY */
/*     CALTECH AND NASA FOR ALL THIRD-PARTY CLAIMS RESULTING FROM THE */
/*     ACTIONS OF RECIPIENT IN THE USE OF THE SOFTWARE. */

/* $ Required_Reading */

/*     GF */
/*     SPK */
/*     TIME */
/*     NAIF_IDS */
/*     FRAMES */

/* $ Keywords */

/*     GEOMETRY */
/*     PRIVATE */
/*     SEARCH */

/* $ Declarations */
/* $ Abstract */

/*     This file contains public, global parameter declarations */
/*     for the SPICELIB Geometry Finder (GF) subsystem. */

/* $ Disclaimer */

/*     THIS SOFTWARE AND ANY RELATED MATERIALS WERE CREATED BY THE */
/*     CALIFORNIA INSTITUTE OF TECHNOLOGY (CALTECH) UNDER A U.S. */
/*     GOVERNMENT CONTRACT WITH THE NATIONAL AERONAUTICS AND SPACE */
/*     ADMINISTRATION (NASA). THE SOFTWARE IS TECHNOLOGY AND SOFTWARE */
/*     PUBLICLY AVAILABLE UNDER U.S. EXPORT LAWS AND IS PROVIDED "AS-IS" */
/*     TO THE RECIPIENT WITHOUT WARRANTY OF ANY KIND, INCLUDING ANY */
/*     WARRANTIES OF PERFORMANCE OR MERCHANTABILITY OR FITNESS FOR A */
/*     PARTICULAR USE OR PURPOSE (AS SET FORTH IN UNITED STATES UCC */
/*     SECTIONS 2312-2313) OR FOR ANY PURPOSE WHATSOEVER, FOR THE */
/*     SOFTWARE AND RELATED MATERIALS, HOWEVER USED. */

/*     IN NO EVENT SHALL CALTECH, ITS JET PROPULSION LABORATORY, OR NASA */
/*     BE LIABLE FOR ANY DAMAGES AND/OR COSTS, INCLUDING, BUT NOT */
/*     LIMITED TO, INCIDENTAL OR CONSEQUENTIAL DAMAGES OF ANY KIND, */
/*     INCLUDING ECONOMIC DAMAGE OR INJURY TO PROPERTY AND LOST PROFITS, */
/*     REGARDLESS OF WHETHER CALTECH, JPL, OR NASA BE ADVISED, HAVE */
/*     REASON TO KNOW, OR, IN FACT, SHALL KNOW OF THE POSSIBILITY. */

/*     RECIPIENT BEARS ALL RISK RELATING TO QUALITY AND PERFORMANCE OF */
/*     THE SOFTWARE AND ANY RELATED MATERIALS, AND AGREES TO INDEMNIFY */
/*     CALTECH AND NASA FOR ALL THIRD-PARTY CLAIMS RESULTING FROM THE */
/*     ACTIONS OF RECIPIENT IN THE USE OF THE SOFTWARE. */

/* $ Required_Reading */

/*     GF */

/* $ Keywords */

/*     GEOMETRY */
/*     ROOT */

/* $ Restrictions */

/*     None. */

/* $ Author_and_Institution */

/*     N.J. Bachman      (JPL) */
/*     L.E. Elson        (JPL) */
/*     E.D. Wright       (JPL) */

/* $ Literature_References */

/*     None. */

/* $ Version */

/* -    SPICELIB Version 1.3.0, 01-OCT-2011 (NJB) */

/*       Added NWILUM parameter. */

/* -    SPICELIB Version 1.2.0, 14-SEP-2010 (EDW) */

/*       Added NWPA parameter. */

/* -    SPICELIB Version 1.1.0, 08-SEP-2009 (EDW) */

/*       Added NWRR parameter. */
/*       Added NWUDS parameter. */

/* -    SPICELIB Version 1.0.0, 21-FEB-2009 (NJB) (LSE) (EDW) */

/* -& */

/*     Root finding parameters: */

/*     CNVTOL is the default convergence tolerance used by the */
/*     high-level GF search API routines. This tolerance is */
/*     used to terminate searches for binary state transitions: */
/*     when the time at which a transition occurs is bracketed */
/*     by two times that differ by no more than CNVTOL, the */
/*     transition time is considered to have been found. */

/*     Units are TDB seconds. */


/*     NWMAX is the maximum number of windows allowed for user-defined */
/*     workspace array. */

/*        DOUBLE PRECISION      WORK   ( LBCELL : MW, NWMAX ) */

/*     Currently no more than twelve windows are required; the three */
/*     extra windows are spares. */

/*     Callers of GFEVNT can include this file and use the parameter */
/*     NWMAX to declare the second dimension of the workspace array */
/*     if necessary. */


/*     Callers of GFIDST should declare their workspace window */
/*     count using NWDIST. */


/*     Callers of GFSEP should declare their workspace window */
/*     count using NWSEP. */


/*     Callers of GFRR should declare their workspace window */
/*     count using NWRR. */


/*     Callers of GFUDS should declare their workspace window */
/*     count using NWUDS. */


/*     Callers of GFPA should declare their workspace window */
/*     count using NWPA. */


/*     Callers of GFILUM should declare their workspace window */
/*     count using NWILUM. */


/*     ADDWIN is a parameter used to expand each interval of the search */
/*     (confinement) window by a small amount at both ends in order to */
/*     accommodate searches using equality constraints. The loaded */
/*     kernel files must accommodate these expanded time intervals. */


/*     FRMNLN is a string length for frame names. */


/*     NVRMAX is the maximum number of vertices if FOV type is "POLYGON" */


/*     FOVTLN -- maximum length for FOV string. */


/*     Specify the character strings that are allowed in the */
/*     specification of field of view shapes. */


/*     Character strings that are allowed in the */
/*     specification of occultation types: */


/*     Occultation target shape specifications: */


/*     Specify the number of supported occultation types and occultation */
/*     type string length: */


/*     Instrument field-of-view (FOV) parameters */

/*     Maximum number of FOV boundary vectors: */


/*     FOV shape parameters: */

/*        circle */
/*        ellipse */
/*        polygon */
/*        rectangle */


/*     End of file gf.inc. */

/* $ Abstract */

/*     SPICE private include file intended solely for the support of */
/*     SPICE routines. Users should not include this routine in their */
/*     source code due to the volatile nature of this file. */

/*     This file contains private, global parameter declarations */
/*     for the SPICELIB Geometry Finder (GF) subsystem. */

/* $ Disclaimer */

/*     THIS SOFTWARE AND ANY RELATED MATERIALS WERE CREATED BY THE */
/*     CALIFORNIA INSTITUTE OF TECHNOLOGY (CALTECH) UNDER A U.S. */
/*     GOVERNMENT CONTRACT WITH THE NATIONAL AERONAUTICS AND SPACE */
/*     ADMINISTRATION (NASA). THE SOFTWARE IS TECHNOLOGY AND SOFTWARE */
/*     PUBLICLY AVAILABLE UNDER U.S. EXPORT LAWS AND IS PROVIDED "AS-IS" */
/*     TO THE RECIPIENT WITHOUT WARRANTY OF ANY KIND, INCLUDING ANY */
/*     WARRANTIES OF PERFORMANCE OR MERCHANTABILITY OR FITNESS FOR A */
/*     PARTICULAR USE OR PURPOSE (AS SET FORTH IN UNITED STATES UCC */
/*     SECTIONS 2312-2313) OR FOR ANY PURPOSE WHATSOEVER, FOR THE */
/*     SOFTWARE AND RELATED MATERIALS, HOWEVER USED. */

/*     IN NO EVENT SHALL CALTECH, ITS JET PROPULSION LABORATORY, OR NASA */
/*     BE LIABLE FOR ANY DAMAGES AND/OR COSTS, INCLUDING, BUT NOT */
/*     LIMITED TO, INCIDENTAL OR CONSEQUENTIAL DAMAGES OF ANY KIND, */
/*     INCLUDING ECONOMIC DAMAGE OR INJURY TO PROPERTY AND LOST PROFITS, */
/*     REGARDLESS OF WHETHER CALTECH, JPL, OR NASA BE ADVISED, HAVE */
/*     REASON TO KNOW, OR, IN FACT, SHALL KNOW OF THE POSSIBILITY. */

/*     RECIPIENT BEARS ALL RISK RELATING TO QUALITY AND PERFORMANCE OF */
/*     THE SOFTWARE AND ANY RELATED MATERIALS, AND AGREES TO INDEMNIFY */
/*     CALTECH AND NASA FOR ALL THIRD-PARTY CLAIMS RESULTING FROM THE */
/*     ACTIONS OF RECIPIENT IN THE USE OF THE SOFTWARE. */

/* $ Required_Reading */

/*     GF */

/* $ Keywords */

/*     GEOMETRY */
/*     ROOT */

/* $ Restrictions */

/*     None. */

/* $ Author_and_Institution */

/*     N.J. Bachman      (JPL) */
/*     E.D. Wright       (JPL) */

/* $ Literature_References */

/*     None. */

/* $ Version */

/* -    SPICELIB Version 1.0.0, 17-FEB-2009 (NJB) (EDW) */

/* -& */

/*     The set of supported coordinate systems */

/*        System          Coordinates */
/*        ----------      ----------- */
/*        Rectangular     X, Y, Z */
/*        Latitudinal     Radius, Longitude, Latitude */
/*        Spherical       Radius, Colatitude, Longitude */
/*        RA/Dec          Range, Right Ascension, Declination */
/*        Cylindrical     Radius, Longitude, Z */
/*        Geodetic        Longitude, Latitude, Altitude */
/*        Planetographic  Longitude, Latitude, Altitude */

/*     Below we declare parameters for naming coordinate systems. */
/*     User inputs naming coordinate systems must match these */
/*     when compared using EQSTR. That is, user inputs must */
/*     match after being left justified, converted to upper case, */
/*     and having all embedded blanks removed. */


/*     Below we declare names for coordinates. Again, user */
/*     inputs naming coordinates must match these when */
/*     compared using EQSTR. */


/*     Note that the RA parameter value below matches */

/*        'RIGHT ASCENSION' */

/*     when extra blanks are compressed out of the above value. */


/*     Parameters specifying types of vector definitions */
/*     used for GF coordinate searches: */

/*     All string parameter values are left justified, upper */
/*     case, with extra blanks compressed out. */

/*     POSDEF indicates the vector is defined by the */
/*     position of a target relative to an observer. */


/*     SOBDEF indicates the vector points from the center */
/*     of a target body to the sub-observer point on */
/*     that body, for a given observer and target. */


/*     SOBDEF indicates the vector points from the center */
/*     of a target body to the surface intercept point on */
/*     that body, for a given observer, ray, and target. */


/*     Number of workspace windows used by ZZGFREL: */


/*     Number of additional workspace windows used by ZZGFLONG: */


/*     Index of "existence window" used by ZZGFCSLV: */


/*     Progress report parameters: */

/*     MXBEGM, */
/*     MXENDM    are, respectively, the maximum lengths of the progress */
/*               report message prefix and suffix. */

/*     Note: the sum of these lengths, plus the length of the */
/*     "percent complete" substring, should not be long enough */
/*     to cause wrap-around on any platform's terminal window. */


/*     Total progress report message length upper bound: */


/*     End of file zzgf.inc. */

/* $ Abstract */

/*     Include file zzabcorr.inc */

/*     SPICE private file intended solely for the support of SPICE */
/*     routines.  Users should not include this file directly due */
/*     to the volatile nature of this file */

/*     The parameters below define the structure of an aberration */
/*     correction attribute block. */

/* $ Disclaimer */

/*     THIS SOFTWARE AND ANY RELATED MATERIALS WERE CREATED BY THE */
/*     CALIFORNIA INSTITUTE OF TECHNOLOGY (CALTECH) UNDER A U.S. */
/*     GOVERNMENT CONTRACT WITH THE NATIONAL AERONAUTICS AND SPACE */
/*     ADMINISTRATION (NASA). THE SOFTWARE IS TECHNOLOGY AND SOFTWARE */
/*     PUBLICLY AVAILABLE UNDER U.S. EXPORT LAWS AND IS PROVIDED "AS-IS" */
/*     TO THE RECIPIENT WITHOUT WARRANTY OF ANY KIND, INCLUDING ANY */
/*     WARRANTIES OF PERFORMANCE OR MERCHANTABILITY OR FITNESS FOR A */
/*     PARTICULAR USE OR PURPOSE (AS SET FORTH IN UNITED STATES UCC */
/*     SECTIONS 2312-2313) OR FOR ANY PURPOSE WHATSOEVER, FOR THE */
/*     SOFTWARE AND RELATED MATERIALS, HOWEVER USED. */

/*     IN NO EVENT SHALL CALTECH, ITS JET PROPULSION LABORATORY, OR NASA */
/*     BE LIABLE FOR ANY DAMAGES AND/OR COSTS, INCLUDING, BUT NOT */
/*     LIMITED TO, INCIDENTAL OR CONSEQUENTIAL DAMAGES OF ANY KIND, */
/*     INCLUDING ECONOMIC DAMAGE OR INJURY TO PROPERTY AND LOST PROFITS, */
/*     REGARDLESS OF WHETHER CALTECH, JPL, OR NASA BE ADVISED, HAVE */
/*     REASON TO KNOW, OR, IN FACT, SHALL KNOW OF THE POSSIBILITY. */

/*     RECIPIENT BEARS ALL RISK RELATING TO QUALITY AND PERFORMANCE OF */
/*     THE SOFTWARE AND ANY RELATED MATERIALS, AND AGREES TO INDEMNIFY */
/*     CALTECH AND NASA FOR ALL THIRD-PARTY CLAIMS RESULTING FROM THE */
/*     ACTIONS OF RECIPIENT IN THE USE OF THE SOFTWARE. */

/* $ Parameters */

/*     An aberration correction attribute block is an array of logical */
/*     flags indicating the attributes of the aberration correction */
/*     specified by an aberration correction string.  The attributes */
/*     are: */

/*        - Is the correction "geometric"? */

/*        - Is light time correction indicated? */

/*        - Is stellar aberration correction indicated? */

/*        - Is the light time correction of the "converged */
/*          Newtonian" variety? */

/*        - Is the correction for the transmission case? */

/*        - Is the correction relativistic? */

/*    The parameters defining the structure of the block are as */
/*    follows: */

/*       NABCOR    Number of aberration correction choices. */

/*       ABATSZ    Number of elements in the aberration correction */
/*                 block. */

/*       GEOIDX    Index in block of geometric correction flag. */

/*       LTIDX     Index of light time flag. */

/*       STLIDX    Index of stellar aberration flag. */

/*       CNVIDX    Index of converged Newtonian flag. */

/*       XMTIDX    Index of transmission flag. */

/*       RELIDX    Index of relativistic flag. */

/*    The following parameter is not required to define the block */
/*    structure, but it is convenient to include it here: */

/*       CORLEN    The maximum string length required by any aberration */
/*                 correction string */

/* $ Author_and_Institution */

/*     N.J. Bachman    (JPL) */

/* $ Literature_References */

/*     None. */

/* $ Version */

/* -    SPICELIB Version 1.0.0, 18-DEC-2004 (NJB) */

/* -& */
/*     Number of aberration correction choices: */


/*     Aberration correction attribute block size */
/*     (number of aberration correction attributes): */


/*     Indices of attributes within an aberration correction */
/*     attribute block: */


/*     Maximum length of an aberration correction string: */


/*     End of include file zzabcorr.inc */

/* $ Brief_I/O */

/*     VARIABLE  I/O  DESCRIPTION */
/*     --------  ---  -------------------------------------------------- */
/*     METHOD     I   Computation method. */
/*     TRGID      I   Target ID code. */
/*     ET         I   Computation epoch. */
/*     FIXREF     I   Reference frame name. */
/*     ABCORR     I   Aberration correction. */
/*     OBSID      I   Observer ID code. */
/*     RADII      I   Target radii. */
/*     STATE      O   State used to define coordinates. */

/* $ Detailed_Input */

/*     METHOD      is a short string providing parameters defining */
/*                 the computation method to be used. Any value */
/*                 supported by SUBPNT may be used. */


/*     TRGID      is the NAIF ID code of the target object. */

/*                *This routine assumes that the target is modeled */
/*                as a tri-axial ellipsoid.* */


/*     ET         is the time, expressed as ephemeris seconds past J2000 */
/*                TDB, at which the specified state is to be computed. */


/*     FIXREF     is the name of the reference frame relative to which */
/*                the state of interest is specified. */

/*                FIXREF must be centered on the target body. */

/*                Case, leading and trailing blanks are not significant */
/*                in the string FIXREF. */


/*     ABCORR     indicates the aberration corrections to be applied to */
/*                the state of the target body to account for one-way */
/*                light time and stellar aberration. The orientation */
/*                of the target body will also be corrected for one-way */
/*                light time when light time corrections are requested. */

/*                Supported aberration correction options for */
/*                observation (case where radiation is received by */
/*                observer at ET) are: */

/*                   NONE           No correction. */
/*                   LT             Light time only. */
/*                   LT+S           Light time and stellar aberration. */
/*                   CN             Converged Newtonian (CN) light time. */
/*                   CN+S           CN light time and stellar aberration. */

/*                Supported aberration correction options for */
/*                transmission (case where radiation is emitted from */
/*                observer at ET) are: */

/*                   XLT            Light time only. */
/*                   XLT+S          Light time and stellar aberration. */
/*                   XCN            Converged Newtonian (CN) light time. */
/*                   XCN+S          CN light time and stellar aberration. */

/*                For detailed information, see the geometry finder */
/*                required reading, gf.req.  Also see the header of */
/*                SPKEZR, which contains a detailed discussion of */
/*                aberration corrections. */

/*                Case, leading and trailing blanks are not significant */
/*                in the string ABCORR. */


/*     OBSID      is the NAIF ID code of the observer. */


/*     RADII      is an array containing three radii defining */
/*                a reference ellipsoid for the target body. */

/* $ Detailed_Output */

/*     STATE     is the state of the sub-observer point at ET. */
/*               The first three components of STATE contain the */
/*               sub-observer point itself; the last three */
/*               components contain the derivative with respect to */
/*               time of the position. The state is expressed */
/*               relative to the body-fixed frame designated by */
/*               FIXREF. */

/*               Units are km and km/s. */

/* $ Parameters */

/*     None. */

/* $ Exceptions */

/*     1)  If the aberration correction ABCORR is not recognized, */
/*         the error will be diagnosed by routines in the call tree */
/*         of this routine. */

/*     2)  If the frame FIXREF is not recognized by the frames */
/*         subsystem, the error will be diagnosed by routines in the */
/*         call tree of this routine. */

/*     3)  FIXREF must be centered on the target body; if it isn't, */
/*         the error will be diagnosed by routines in the call tree */
/*         of this routine. */

/*     4)  Any error that occurs while look up the state of the target */
/*         or observer will be diagnosed by routines in the call tree of */
/*         this routine. */

/*     5)  Any error that occurs while look up the orientation of */
/*         the target will be diagnosed by routines in the call tree of */
/*         this routine. */

/*     6)  If the input method is not recognized, the error */
/*         SPICE(NOTSUPPORTED) will be signaled. */

/* $ Files */

/*     Appropriate kernels must be loaded by the calling program before */
/*     this routine is called. */

/*     The following data are required: */

/*        - SPK data: ephemeris data for target and observer must be */
/*          loaded. If aberration corrections are used, the states of */
/*          target and observer relative to the solar system barycenter */
/*          must be calculable from the available ephemeris data. */
/*          Typically ephemeris data are made available by loading one */
/*          or more SPK files via FURNSH. */

/*        - PCK data: if the target body shape is modeled as an */
/*          ellipsoid, triaxial radii for the target body must be loaded */
/*          into the kernel pool. Typically this is done by loading a */
/*          text PCK file via FURNSH. */

/*        - Further PCK data: rotation data for the target body must be */
/*          loaded. These may be provided in a text or binary PCK file. */

/*        - Frame data: if a frame definition is required to convert the */
/*          observer and target states to the body-fixed frame of the */
/*          target, that definition must be available in the kernel */
/*          pool. Typically the definition is supplied by loading a */
/*          frame kernel via FURNSH. */

/*     In all cases, kernel data are normally loaded once per program */
/*     run, NOT every time this routine is called. */

/* $ Particulars */

/*     This routine isolates the computation of the sub-observer state */
/*     (that is, the sub-observer point and its derivative with respect */
/*     to time). */

/*     This routine is used by the GF coordinate utility routines in */
/*     order to solve for time windows on which specified mathematical */
/*     conditions involving coordinates are satisfied. The role of */
/*     this routine is to provide Cartesian state vectors enabling */
/*     the GF coordinate utilities to determine the signs of the */
/*     derivatives with respect to time of coordinates of interest. */

/* $ Examples */

/*     See ZZGFCOST. */

/* $ Restrictions */

/*     1)  This routine is restricted to use with ellipsoidal target */
/*         shape models. */

/*     2)  The computations performed by this routine are intended */
/*         to be compatible with those performed by the SPICE */
/*         routine SUBPNT. If that routine changes, this routine */
/*         may need to be updated. */

/*     3)  This routine presumes that error checking of inputs */
/*         has, where possible, already been performed by the */
/*         GF coordinate utility initialization routine. */

/*     4)  The interface and functionality of this set of routines may */
/*         change without notice. These routines should be called only */
/*         by SPICELIB routines. */

/* $ Literature_References */

/*     None. */

/* $ Author_and_Institution */

/*     N.J. Bachman   (JPL) */

/* $ Version */

/* -    SPICELIB Version 2.0.0 12-MAY-2009 (NJB) */

/*        Upgraded to support targets and observers having */
/*        no names associated with their ID codes. */

/* -    SPICELIB Version 1.0.0 05-MAR-2009 (NJB) */

/* -& */
/* $ Index_Entries */

/*     sub-observer state */

/* -& */

/*     SPICELIB functions */


/*     Local parameters */


/*     Local variables */


/*     Saved variables */


/*     Initial values */


/*     Standard SPICE error handling. */

    if (return_()) {
	return 0;
    }
    chkin_("ZZGFSSOB", (ftnlen)8);
    if (first || *trgid != prvtrg) {
	bodc2s_(trgid, svtarg, (ftnlen)36);
	prvtrg = *trgid;
    }
    if (first || *obsid != prvobs) {
	bodc2s_(obsid, svobs, (ftnlen)36);
	prvobs = *obsid;
    }
    first = FALSE_;

/*     Parse the aberration correction specifier. */

    zzprscor_(abcorr, attblk, abcorr_len);
    geom = attblk[0];
    uselt = attblk[1];
    usestl = attblk[2];
    xmit = attblk[4];

/*     Decide whether the sub-observer point is computed using */
/*     the "near point" or "surface intercept" method. Only */
/*     ellipsoids may be used a shape models for this computation. */

    if (eqstr_(method, "Near point: ellipsoid", method_len, (ftnlen)21)) {
	near__ = TRUE_;
    } else if (eqstr_(method, "Intercept: ellipsoid", method_len, (ftnlen)20))
	     {
	near__ = FALSE_;
    } else {
	setmsg_("Sub-observer point computation method # is not supported by"
		" this routine.", (ftnlen)73);
	errch_("#", method, (ftnlen)1, method_len);
	sigerr_("SPICE(NOTSUPPORTED)", (ftnlen)19);
	chkout_("ZZGFSSOB", (ftnlen)8);
	return 0;
    }
    if (geom) {

/*        This is the geometric case. */

/*        We need to check the body-fixed reference frame here. */

	namfrm_(fixref, &frcode, fixref_len);
	frinfo_(&frcode, &center, &frclss, &clssid, &fnd);
	if (failed_()) {
	    chkout_("ZZGFSSOB", (ftnlen)8);
	    return 0;
	}
	if (! fnd) {
	    setmsg_("Input reference frame # was not recognized.", (ftnlen)43)
		    ;
	    errch_("#", fixref, (ftnlen)1, fixref_len);
	    sigerr_("SPICE(NOFRAME)", (ftnlen)14);
	    chkout_("ZZGFSSOB", (ftnlen)8);
	    return 0;
	}
	if (center != *trgid) {
	    setmsg_("Input reference frame # is centered on body # instead o"
		    "f body #.", (ftnlen)64);
	    errch_("#", fixref, (ftnlen)1, fixref_len);
	    errint_("#", &center, (ftnlen)1);
	    errint_("#", trgid, (ftnlen)1);
	    sigerr_("SPICE(INVALIDFRAME)", (ftnlen)19);
	    chkout_("ZZGFSSOB", (ftnlen)8);
	    return 0;
	}

/*        Get the state of the target with respect to the observer, */
/*        expressed relative to the target body-fixed frame. We don't */
/*        need to propagate states to the solar system barycenter in */
/*        this case. */

	spkgeo_(trgid, et, fixref, obsid, fxtsta, &lt, fixref_len);
	if (failed_()) {
	    chkout_("ZZGFSSOB", (ftnlen)8);
	    return 0;
	}

/*        Compute the state of the observer with respect to the target */
/*        in the body-fixed frame. */

	vminug_(fxtsta, &c__6, fxosta);

/*        Now we can obtain the surface velocity of the sub-observer */
/*        point. */

	if (near__) {

/*           The sub-observer point method is "near point." */

	    dnearp_(fxosta, radii, &radii[1], &radii[2], fxpsta, dalt, &found)
		    ;
	    if (! found) {
		setmsg_("The sub-observer state could could not be computed "
			"because the velocity was not well defined. DNEARP re"
			"turned \"not found.\"", (ftnlen)122);
		sigerr_("SPICE(DEGENERATECASE)", (ftnlen)21);
		chkout_("ZZGFSSOB", (ftnlen)8);
		return 0;
	    }
	} else {

/*           The sub-observer point method is "surface */
/*           intercept point." The ray direction is simply */
/*           the negative of the observer's position relative */
/*           to the target center. */

	    vminug_(fxosta, &c__6, raysta);
	    surfpv_(fxosta, raysta, radii, &radii[1], &radii[2], fxpsta, &
		    found);

/*           Although in general it's not an error for SURFPV to */
/*           be unable to compute an intercept state, it *is* */
/*           an error in this case, since the ray points toward */
/*           the center of the target. */

	    if (! found) {
		setmsg_("The sub-observer state could could not be computed "
			"because the velocity was not well defined. SURFPV re"
			"turned \"not found.\"", (ftnlen)122);
		sigerr_("SPICE(DEGENERATECASE)", (ftnlen)21);
		chkout_("ZZGFSSOB", (ftnlen)8);
		return 0;
	    }
	}
    } else if (uselt) {

/*        Light time and possibly stellar aberration corrections are */
/*        applied. */

/*        Most our work consists of getting ready to call either of the */
/*        SPICELIB routines DNEARP or SURFPV. In order to make this */
/*        call, we'll need the velocity of the observer relative to the */
/*        target body's center in the target body-fixed frame. We must */
/*        evaluate the rotation state of the target at the correct */
/*        epoch, and account for the rate of change of light time, if */
/*        light time corrections are used. The algorithm we use depends */
/*        on the algorithm used in SUBPNT, since we're computing the */
/*        derivative with respect to time of the solution found by that */
/*        routine. */

/*        In this algorithm, we must take into account the fact that */
/*        SUBPNT performs light time and stellar aberration corrections */
/*        for the sub-observer point, not for the center of the target */
/*        body. */

/*        If light time and stellar aberration corrections are used, */

/*           - Find the aberration corrected sub-observer point and the */
/*             light time-corrected epoch TRGEPC associated with the */
/*             sub-observer point. */

/*           - Use TRGEPC to find the position of the target relative to */
/*             the solar system barycenter. */

/*           - Use TRGEPC to find the orientation of the target relative */
/*             to the J2000 reference frame. */

/*           - Find the light-time corrected position of the */
/*             sub-observer point; use this to compute the stellar */
/*             aberration offset that applies to the sub-observer point, */
/*             as well as the velocity of this offset. */

/*           - Find the corrected state of the target center as seen */
/*             from the observer, where the corrections are those */
/*             applicable to the sub-observer point. */

/*           - Negate the corrected target center state to obtain the */
/*             state of the observer relative to the target. */

/*           - Express the state of the observer relative to the target */
/*             in the target body fixed frame at TRGEPC. */


/*        Below, we'll use the convention that vectors expressed */
/*        relative to the body-fixed frame have names of the form */

/*           FX* */

/*        Note that SUBPNT will signal an error if FIXREF is not */
/*        actually centered on the target body. */

	subpnt_(method, svtarg, et, fixref, abcorr, svobs, spoint, &trgepc, 
		srfvec, method_len, (ftnlen)36, fixref_len, abcorr_len, (
		ftnlen)36);

/*        Get J2000-relative states of observer and target with respect */
/*        to the solar system barycenter at their respective epochs of */
/*        participation. */

	spkssb_(obsid, et, "J2000", ssbobs, (ftnlen)5);
	spkssb_(trgid, &trgepc, "J2000", ssbtg0, (ftnlen)5);

/*        Get the uncorrected J2000 to body-fixed to state */
/*        transformation at TRGEPC. */

	sxform_("J2000", fixref, &trgepc, xform, (ftnlen)5, fixref_len);
	if (failed_()) {
	    chkout_("ZZGFSSOB", (ftnlen)8);
	    return 0;
	}

/*        Initialize the state of the sub-observer point in the */
/*        body-fixed frame. At this point we don't know the */
/*        point's velocity; set it to zero. */

	moved_(spoint, &c__3, fxpsta);
	cleard_(&c__3, &fxpsta[3]);
	if (usestl) {

/*           We're going to need the acceleration of the observer */
/*           relative to the SSB. Compute this now. */

	    for (i__ = 1; i__ <= 2; ++i__) {

/*              The epoch is ET -/+ TDELTA. */

		t = *et + ((i__ << 1) - 3) * 1.;
		spkssb_(obsid, &t, "J2000", &obssta[(i__1 = i__ * 6 - 6) < 12 
			&& 0 <= i__1 ? i__1 : s_rnge("obssta", i__1, "zzgfss"
			"ob_", (ftnlen)652)], (ftnlen)5);
	    }
	    if (failed_()) {
		chkout_("ZZGFSSOB", (ftnlen)8);
		return 0;
	    }

/*           Compute the observer's acceleration using a quadratic */
/*           approximation. */

	    qderiv_(&c__3, &obssta[3], &obssta[9], &c_b40, acc);
	}

/*        The rest of the algorithm is iterative. On the first */
/*        iteration, we don't have a good estimate of the velocity */
/*        of the sub-observer point relative to the body-fixed */
/*        frame. Since we're using this velocity as an input */
/*        to the aberration velocity computations, we */
/*        expect that treating this velocity as zero on the first */
/*        pass yields a reasonable estimate. On the second pass, */
/*        we'll use the velocity derived on the first pass. */

	cleard_(&c__3, fxpvel);

/*        We'll also estimate the rate of change of light time */
/*        as zero on the first pass. */

	dlt = 0.;
	for (i__ = 1; i__ <= 2; ++i__) {

/*           Correct the target's velocity for the rate of */
/*           change of light time. */

	    if (xmit) {
		scale = dlt + 1.;
	    } else {
		scale = 1. - dlt;
	    }

/*           Scale the velocity portion of the target state to */
/*           correct the velocity for the rate of change of light */
/*           time. */

	    moved_(ssbtg0, &c__3, ssbtrg);
	    vscl_(&scale, &ssbtg0[3], &ssbtrg[3]);

/*           Get the state of the target with respect to the observer. */

	    vsubg_(ssbtrg, ssbobs, &c__6, obstrg);

/*           Correct the J2000 to body-fixed state transformation matrix */
/*           for the rate of change of light time. */

	    zzcorsxf_(&xmit, &dlt, xform, corxfm);

/*           Invert CORXFM to obtain the corrected */
/*           body-fixed to J2000 state transformation. */

	    invstm_(corxfm, corxfi);

/*           Convert the sub-observer point state to the J2000 frame. */

	    mxvg_(corxfi, fxpsta, &c__6, &c__6, pntsta);

/*           Find the J2000-relative state of the sub-observer */
/*           point with respect to the target. */

	    vaddg_(obstrg, pntsta, &c__6, obspnt);
	    if (usestl) {

/*              Now compute the stellar aberration correction */
/*              applicable to OBSPNT. We need the velocity of */
/*              this correction as well. */

		zzstelab_(&xmit, acc, &ssbobs[3], obspnt, sa, savel);
		moved_(sa, &c__3, sastat);
		moved_(savel, &c__3, &sastat[3]);

/*              Adding the stellar aberration state to the target center */
/*              state gives us the state of the target center with */
/*              respect to the observer, corrected for the aberrations */
/*              applicable to the sub-observer point. */
		vaddg_(obstrg, sastat, &c__6, stemp);
	    } else {
		moved_(obstrg, &c__6, stemp);
	    }

/*           Convert STEMP to the body-fixed reference frame. */

	    mxvg_(corxfm, stemp, &c__6, &c__6, fxtsta);

/*           At long last, compute the state of the observer */
/*           with respect to the target in the body-fixed frame. */

	    vminug_(fxtsta, &c__6, fxosta);

/*           Now we can obtain the surface velocity of the */
/*           sub-observer point. */

	    if (near__) {

/*              The sub-observer point method is "near point." */

		dnearp_(fxosta, radii, &radii[1], &radii[2], fxpsta, dalt, &
			found);
		if (! found) {
		    setmsg_("The sub-observer state could could not be compu"
			    "ted because the velocity was not well defined.  "
			    "DNEARP returned \"not found.\"", (ftnlen)123);
		    sigerr_("SPICE(DEGENERATECASE)", (ftnlen)21);
		    chkout_("ZZGFSSOB", (ftnlen)8);
		    return 0;
		}
	    } else {

/*              The sub-observer point method is "surface intercept */
/*              point." The ray direction is simply the negative of the */
/*              observer's position relative to the target center. */

		vminug_(fxosta, &c__6, raysta);
		surfpv_(fxosta, raysta, radii, &radii[1], &radii[2], fxpsta, &
			found);

/*              Although in general it's not an error for SURFPV to be */
/*              unable to compute an intercept state, it *is* an error */
/*              in this case, since the ray points toward the center of */
/*              the target. */

		if (! found) {
		    setmsg_("The sub-observer state could could not be compu"
			    "ted because the velocity was not well defined. S"
			    "URFPV returned \"not found.\"", (ftnlen)122);
		    sigerr_("SPICE(DEGENERATECASE)", (ftnlen)21);
		    chkout_("ZZGFSSOB", (ftnlen)8);
		    return 0;
		}
	    }

/*           At this point we can update the surface point */
/*           velocity and light time derivative estimates. */

/*           In order to compute the light time rate, we'll */
/*           need the J2000-relative velocity of the sub-observer */
/*           point with respect to the observer. First convert */
/*           the sub-observer state to the J2000 frame, then */
/*           add the result to the state of the target center */
/*           with respect to the observer. */

	    mxvg_(corxfi, fxpsta, &c__6, &c__6, pntsta);
	    vaddg_(obstrg, pntsta, &c__6, obspnt);

/*           Now that we have an improved estimate of the */
/*           sub-observer state, we can estimate the rate of */
/*           change of light time as */

/*              range rate */
/*              ---------- */
/*                  c */


/*           If we're correcting for stellar aberration, *ideally* we */
/*           should remove that correction now, since the light time */
/*           rate is based on light time between the observer and the */
/*           light-time corrected sub-observer point. But the error made */
/*           by including stellar aberration is too small to make it */
/*           worthwhile to make this adjustment. */

	    vhat_(obspnt, upos);
	    dlt = vdot_(&obspnt[3], upos) / clight_();

/*           With FXPVEL and DLT updated, we'll repeat our */
/*           computations. */

	}
    } else {

/*        We should never get here. */

	setmsg_("Aberration correction # was not recognized.", (ftnlen)43);
	errch_("#", abcorr, (ftnlen)1, abcorr_len);
	sigerr_("SPICE(NOTSUPPORTED)", (ftnlen)19);
	chkout_("ZZGFSSOB", (ftnlen)8);
	return 0;
    }

/*     Copy the computed state to the output argument STATE. */

    moved_(fxpsta, &c__6, state);
    chkout_("ZZGFSSOB", (ftnlen)8);
    return 0;
} /* zzgfssob_ */