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dvdot_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

   dvdot_c ( Derivative of Vector Dot Product, 3-D ) 

   SpiceDouble dvdot_c ( ConstSpiceDouble s1[6],
                         ConstSpiceDouble s2[6] )

Abstract

   Compute the derivative of the dot product of two double
   precision position vectors.

Required_Reading

   None.

Keywords

   DERIVATIVE
   VECTOR


Brief_I/O

   VARIABLE  I/O  DESCRIPTION
   --------  ---  --------------------------------------------------
   s1         I   First state vector in the dot product.
   s2         I   Second state vector in the dot product.

   The function returns the derivative of the dot product <s1,s2>

Detailed_Input

   s1          is any state vector. The components are in order
               (x, y, z, dx/dt, dy/dt, dz/dt )

   s2          is any state vector.

Detailed_Output

   The function returns the derivative of the dot product of the
   position portions of the two state vectors `s1' and `s2'.

Parameters

   None.

Exceptions

   Error free.

Files

   None.

Particulars

   Given two state vectors `s1' and `s2' made up of position and
   velocity components (p1,v1) and (p2,v2) respectively,
   dvdot_c calculates the derivative of the dot product of `p1' and `p2',
   i.e. the time derivative

         d
         -- < p1, p2 > = < v1, p2 > + < p1, v2 >
         dt

   where <,> denotes the dot product operation.

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) Suppose that given two state vectors whose position components
      are unit vectors, and that we need to compute the rate of
      change of the angle between the two vectors.

      Example code begins here.


      /.
         Program dvdot_ex1
      ./
      #include <math.h>
      #include <stdio.h>
      #include "SpiceUsr.h"

      int main( )
      {

         /.
         Local variables.
         ./
         SpiceDouble          dtheta;

         /.
         Define the two state vectors whose position
         components are unit vectors.
         ./
         SpiceDouble          s1     [6] = {
                                      7.2459e-01,  6.6274e-01,  1.8910e-01,
                                     -1.5990e-06,  1.6551e-06,  7.4873e-07 };

         SpiceDouble          s2     [6] = {
                                      8.4841e-01, -4.7790e-01, -2.2764e-01,
                                      1.0951e-07,  1.0695e-07,  4.8468e-08 };

         /.
         We know that the Cosine of the angle `theta' between them
         is given by

            cos(theta) = vdot_c(s1,s2)

         Thus by the chain rule, the derivative of the angle is
         given by:

            sin(theta) dtheta/dt = dvdot_c(s1,s2)

         Thus for values of `theta' away from zero we can compute
         dtheta/dt as:
         ./
         dtheta = dvdot_c(s1,s2) / sqrt( 1 - pow( vdot_c(s1,s2 ), 2 ) );

         printf( "Rate of change of angle between S1 and S2: %17.12f\n",
                                                                  dtheta );

         return ( 0 );
      }


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


      Rate of change of angle between S1 and S2:   -0.000002232415


      Note that if the position components of `s1' and `s2' are parallel,
      the derivative of the  angle between the positions does not
      exist. Any code that computes the derivative of the angle
      between two position vectors should account for the case
      when the position components are parallel.

Restrictions

   1)  The user is responsible for determining that the states `s1' and
       `s2' are not so large as to cause numeric overflow. In most
       cases this won't present a problem.

   2)  An implicit assumption exists that `s1' and `s2' are specified in
       the same reference frame. If this is not the case, the
       numerical result has no meaning.

Literature_References

   None.

Author_and_Institution

   J. Diaz del Rio     (ODC Space)
   W.L. Taber          (JPL)
   E.D. Wright         (JPL)

Version

   -CSPICE Version 1.0.1, 26-MAY-2021 (JDR)

       Edited the header to comply with NAIF standard. Added complete
       code examples. Added entry #2 to -Restrictions section.

       Re-ordered header sections.

   -CSPICE Version 1.0.0, 07-JUL-1999 (EDW) (WLT)

Index_Entries

   Compute the derivative of a dot product
Fri Dec 31 18:41:05 2021