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dcyldr_c

Table of contents
Procedure
Abstract
Required_Reading
Keywords
Brief_I/O
Detailed_Input
Detailed_Output
Parameters
Exceptions
Files
Particulars
Examples
Restrictions
Literature_References
Author_and_Institution
Version
Index_Entries

Procedure

   dcyldr_c (Derivative of cylindrical w.r.t. rectangular ) 

   void dcyldr_c ( SpiceDouble    x,
                   SpiceDouble    y,
                   SpiceDouble    z,
                   SpiceDouble    jacobi[3][3] )

Abstract

   Compute the Jacobian matrix of the transformation from
   rectangular to cylindrical coordinates.

Required_Reading

   None.

Keywords

   COORDINATES
   DERIVATIVES
   MATRIX


Brief_I/O

   VARIABLE  I/O  DESCRIPTION
   --------  ---  --------------------------------------------------
   x          I   X-coordinate of point.
   y          I   Y-coordinate of point.
   z          I   Z-coordinate of point.
   jacobi     O   Matrix of partial derivatives.

Detailed_Input

   x,
   y,
   z           are the rectangular coordinates of the point at
               which the Jacobian of the map from rectangular
               to cylindrical coordinates is desired.

Detailed_Output

   jacobi      is the matrix of partial derivatives of the conversion
               between rectangular and cylindrical coordinates. It
               has the form

                  .-                            -.
                  |  dr  /dx   dr  /dy  dr  /dz  |
                  |  dlon/dx   dlon/dy  dlon/dz  |
                  |  dz  /dx   dz  /dy  dz  /dz  |
                  `-                            -'

               evaluated at the input values of x, y, and z.

Parameters

   None.

Exceptions

   1)  If the input point is on the Z-axis (X = 0 and Y = 0), the
       Jacobian is undefined, the error SPICE(POINTONZAXIS) is
       signaled by a routine in the call tree of this routine.

Files

   None.

Particulars

   When performing vector calculations with velocities it is
   usually most convenient to work in rectangular coordinates.
   However, once the vector manipulations have been performed,
   it is often desirable to convert the rectangular representations
   into cylindrical coordinates to gain insights about phenomena
   in this coordinate frame.

   To transform rectangular velocities to derivatives of
   coordinates in a cylindrical system, one uses the Jacobian
   of the transformation between the two systems.

   Given a state in rectangular coordinates

      ( x, y, z, dx, dy, dz )

   the velocity in cylindrical coordinates is given by the matrix
   equation:

                    t          |                     t
      (dr, dlon, dz)   = jacobi|       * (dx, dy, dz)
                               |(x,y,z)

   This routine computes the matrix

            |
      jacobi|
            |(x,y,z)

Examples

   The numerical results shown for this example may differ across
   platforms. The results depend on the SPICE kernels used as
   input, the compiler and supporting libraries, and the machine
   specific arithmetic implementation.

   1) Find the cylindrical state of the Earth as seen from
      Mars in the IAU_MARS reference frame at January 1, 2005 TDB.
      Map this state back to rectangular coordinates as a check.

      Use the meta-kernel shown below to load the required SPICE
      kernels.


         KPL/MK

         File name: dcyldr_ex1.tm

         This meta-kernel is intended to support operation of SPICE
         example programs. The kernels shown here should not be
         assumed to contain adequate or correct versions of data
         required by SPICE-based user applications.

         In order for an application to use this meta-kernel, the
         kernels referenced here must be present in the user's
         current working directory.

         The names and contents of the kernels referenced
         by this meta-kernel are as follows:

            File name                     Contents
            ---------                     --------
            de421.bsp                     Planetary ephemeris
            pck00010.tpc                  Planet orientation and
                                          radii
            naif0009.tls                  Leapseconds


         \begindata

            KERNELS_TO_LOAD = ( 'de421.bsp',
                                'pck00010.tpc',
                                'naif0009.tls'  )

         \begintext

         End of meta-kernel


      Example code begins here.


      /.
         Program dcyldr_ex1
      ./
      #include <stdio.h>
      #include "SpiceUsr.h"

      int main( )
      {

         /.
         Local variables
         ./
         SpiceDouble          clon;
         SpiceDouble          drectn [3];
         SpiceDouble          et;
         SpiceDouble          jacobi [3][3];
         SpiceDouble          lt;
         SpiceDouble          cylvel [3];
         SpiceDouble          rectan [3];
         SpiceDouble          r;
         SpiceDouble          state  [6];
         SpiceDouble          z;

         /.
         Load SPK, PCK and LSK kernels, use a meta kernel for
         convenience.
         ./
         furnsh_c ( "dcyldr_ex1.tm" );

         /.
         Look up the apparent state of earth as seen from Mars
         at January 1, 2005 TDB, relative to the IAU_MARS reference
         frame.
         ./
         str2et_c ( "January 1, 2005 TDB", &et );

         spkezr_c ( "Earth", et, "IAU_MARS", "LT+S", "Mars", state, &lt );

         /.
         Convert position to cylindrical coordinates.
         ./
         reccyl_c ( state, &r, &clon, &z );

         /.
         Convert velocity to cylindrical coordinates.
         ./

         dcyldr_c ( state[0], state[1], state[2], jacobi );

         mxv_c ( jacobi, state+3, cylvel );

         /.
         As a check, convert the cylindrical state back to
         rectangular coordinates.
         ./
         cylrec_c ( r, clon, z, rectan );

         drdcyl_c ( r, clon, z, jacobi );

         mxv_c ( jacobi, cylvel, drectn );

         printf( " \n" );
         printf( "Rectangular coordinates:\n" );
         printf( " \n" );
         printf( " X (km)                 =  %17.8e\n", state[0] );
         printf( " Y (km)                 =  %17.8e\n", state[1] );
         printf( " Z (km)                 =  %17.8e\n", state[2] );
         printf( " \n" );
         printf( "Rectangular velocity:\n" );
         printf( " \n" );
         printf( " dX/dt (km/s)           =  %17.8e\n", state[3] );
         printf( " dY/dt (km/s)           =  %17.8e\n", state[4] );
         printf( " dZ/dt (km/s)           =  %17.8e\n", state[5] );
         printf( " \n" );
         printf( "Cylindrical coordinates:\n" );
         printf( " \n" );
         printf( " Radius    (km)         =  %17.8e\n", r );
         printf( " Longitude (deg)        =  %17.8e\n", clon/rpd_c() );
         printf( " Z         (km)         =  %17.8e\n", z );
         printf( " \n" );
         printf( "Cylindrical velocity:\n" );
         printf( " \n" );
         printf( " d Radius/dt    (km/s)  =  %17.8e\n", cylvel[0] );
         printf( " d Longitude/dt (deg/s) =  %17.8e\n", cylvel[1]/rpd_c() );
         printf( " d Z/dt         (km/s)  =  %17.8e\n", cylvel[2] );
         printf( " \n" );
         printf( "Rectangular coordinates from inverse mapping:\n" );
         printf( " \n" );
         printf( " X (km)                 =  %17.8e\n", rectan[0] );
         printf( " Y (km)                 =  %17.8e\n", rectan[1] );
         printf( " Z (km)                 =  %17.8e\n", rectan[2] );
         printf( " \n" );
         printf( "Rectangular velocity from inverse mapping:\n" );
         printf( " \n" );
         printf( " dX/dt (km/s)           =  %17.8e\n", drectn[0] );
         printf( " dY/dt (km/s)           =  %17.8e\n", drectn[1] );
         printf( " dZ/dt (km/s)           =  %17.8e\n", drectn[2] );
         printf( " \n" );

         return ( 0 );
      }


      When this program was executed on a Mac/Intel/cc/64-bit
      platform, the output was:


      Rectangular coordinates:

       X (km)                 =    -7.60961826e+07
       Y (km)                 =     3.24363805e+08
       Z (km)                 =     4.74704840e+07

      Rectangular velocity:

       dX/dt (km/s)           =     2.29520749e+04
       dY/dt (km/s)           =     5.37601112e+03
       dZ/dt (km/s)           =    -2.08811490e+01

      Cylindrical coordinates:

       Radius    (km)         =     3.33170387e+08
       Longitude (deg)        =     1.03202903e+02
       Z         (km)         =     4.74704840e+07

      Cylindrical velocity:

       d Radius/dt    (km/s)  =    -8.34966283e+00
       d Longitude/dt (deg/s) =    -4.05392876e-03
       d Z/dt         (km/s)  =    -2.08811490e+01

      Rectangular coordinates from inverse mapping:

       X (km)                 =    -7.60961826e+07
       Y (km)                 =     3.24363805e+08
       Z (km)                 =     4.74704840e+07

      Rectangular velocity from inverse mapping:

       dX/dt (km/s)           =     2.29520749e+04
       dY/dt (km/s)           =     5.37601112e+03
       dZ/dt (km/s)           =    -2.08811490e+01

Restrictions

   None.

Literature_References

   None.

Author_and_Institution

   N.J. Bachman        (JPL)
   J. Diaz del Rio     (ODC Space)
   W.L. Taber          (JPL)

Version

   -CSPICE Version 1.0.1, 01-NOV-2021 (JDR)

       Edited the header to comply with NAIF standard.
       Added complete code example.

   -CSPICE Version 1.0.0, 19-JUL-2001 (WLT) (NJB)

Index_Entries

   Jacobian of cylindrical w.r.t. rectangular coordinates
Fri Dec 31 18:41:04 2021