Table of Contents

   Preface - Other Stuff (The Red Shirt topics) (IDL)
   Coding and Use Lessons
      Note About HTML Links
      NAIF Documentation
         Required Reading and Users Guides
         Library Source Code Documentation
         API Documentation
         Tutorials
      Text kernels
         Text kernel format
      Kernels for lessons
         Input kernel files
         Output
   Lesson 1: Kernel Management with the Kernel Subsystem
      Relevant Routines
      Requirements and References
      Programming Task
      Code Solution
         First, create a meta text kernel:
         Now the solution source code:
         Run the code example
   Lesson 2: The Kernel Pool
      Relevant Routines
      Requirements and References
      Programming Task
      Code Solution
         Run the code example
   Lesson 3: Coordinate Conversions
      Relevant Routines
      Requirements and References
      Programming Task
      Code Solution
         Run the code example
   Lesson 4: Advanced Time Manipulation Routines
      Relevant Routines
      Requirements and References
      Programming Task
      Code Solution
         Run the code example
   Lesson 5: Error Handling
      Relevant Routines:
      Requirements and References
      Programming Task
      Code Solution
         Run the code example
   Lesson 6: Windows, and Cells
      Relevant Routines
      Requirements and References
      Programming task:
      Code Solution
         Run the code example
   Lesson 7: Utility and Constants Routines
      Relevant Routines
      Requirements and References
      Programming Task
      Code Solution
         Run the code example
      Programming Task
      Code Solution
         Run the code example

Top

Preface - Other Stuff (The Red Shirt topics) (IDL)

October 20, 2008

The extensive scope of the Icy system's functionality includes features the average user may not expect or appreciate, features NAIF refers to as "Other Stuff." This workbook includes a set of lessons to introduce the beginning to moderate user to such features.

The lessons provide a brief description to several related sets of routines, associated reference documents, a programming task designed to teach the use of the routines, and an example solution to the programming problem.

Top

Coding and Use Lessons

This workbook contains lessons to demonstrate use of the less celebrated Icy routines.

1. Kernel Management with the Kernel Subsystem

2. The Kernel Pool

3. Coordinate Conversions

4. Advanced Time Manipulation Routines

5. Error Handling

6. Windows and Cells

7. Utility and Constants Routines

Top

Note About HTML Links

The HTML version of this lesson contains links pointing to various HTML documents provided with the Toolkit. All of these links are relative and, in order to function, require this document to be in a certain location in the Toolkit HTML documentation directory tree.

In order for the links to be resolved, create a subdirectory called ``lessons'' under the ``doc/html'' directory of the Toolkit tree and copy this document to that subdirectory before loading it into a Web browser.

Top

NAIF Documentation

The technical complexity of the various Icy subsystems mandates an extensive, user-friendly documentation set. The set differs somewhat depending on your choice of development language, FORTRAN, C, IDL, or MATLAB but provides the same information with regards to SPICE operation.

The sources for a user needing information concerning the Icy System or other NAIF product:

-- Required Readings and Users Guides

-- Library Source Code Documentation

-- API Documentation

-- Tutorials

Top

Required Reading and Users Guides

NAIF Required Reading (*.req) documents introduce the functionality of particular Icy subsystems:

 
   cells.req
   ck.req
   cspice.req
   daf.req
   das.req
   ek.req
   ellipses.req
   error.req
   frames.req
   icy.req
   intrdctn.req
   kernel.req
   mice.req
   naif_ids.req
   pck.req
   planes.req
   problems.req
   rotation.req
   scanning.req
   sclk.req
   sets.req
   spc.req
   spk.req
   symbols.req
   time.req
   windows.req
 

 
   brief.ug
   chronos.ug
   ckbrief.ug
   commnt.ug
   convert.ug
   inspekt.ug
   mkspk.ug
   msopck.ug
   simple.ug
   spacit.ug
   spkdiff.ug
   spkmerge.ug
   states.ug
   subpt.ug
   tictoc.ug
   tobin.ug
   toxfr.ug
   version.ug
 

      ../icy/doc/

The Icy distributions include HTML versions of Required Readings and Users Guides, accessible from the HTML documentation directory:

     ../icy/doc/html/index.html

Top

Library Source Code Documentation

All SPICELIB and CSPICE source files include usage and design information incorporated in a comment block known as the "header." (Every toolkit includes either the SPICELIB or CSPICE library.)

A header consists of several marked sections:

-- Procedure: Routine name and one line expansion of the routine's name.

-- Abstract: A tersely worded explanation describing the routine.

-- Copyright: An identification of the copyright holder for the routine.

-- Required_Reading: A list of Icy required reading documents relating to the routine.

-- Brief_I/O: A table of arguments, identifying each as either input, output, or both, with a very brief description of the variable.

-- Detailed_Input & Detailed_Output: An elaboration of the Brief_I/O section providing comprehensive information on argument use.

-- Parameters: Description and declaration of any parameters (constants) specific to the routine.

-- Exceptions: A list of error conditions the routine detects and signals plus a discussion of any other exceptional conditions the routine may encounter.

-- Files: A list of other files needed for the routine to operate.

-- Particulars: A discussion of the routine's function (if needed). This section may also include information relating to "how" and "why" the routine performs an operation and to explain functionality of routines that operate by side effects.

-- Examples: Descriptions and code snippets concerning usage of the routine.

-- Restrictions: Restrictions or warnings concerning use.

-- Literature_References: A list of sources required to understand the algorithms or data used in the routine.

-- Author_and_Institution: The names and affiliations for authors of the routine.

-- Version: A list of edits and the authors of those edits made to the routine since initial delivery to the Icy system.

      ../icy/src/

      ../icy/src/cspice/

Top

API Documentation

The Icy package includes the CSPICE Reference Guide, an index of all CSPICE wrapper APIs with hyperlinks to API specific documentation. Each API documentation page includes cross-links to any other wrapper API mentioned in the document and links to the wrapper source code.

      ...icy/doc/html/cspice/index.html

      ...icy/doc/html/icy/index.html

Top

Tutorials

A set of Microsoft PowerPoint presentations provide a general overview of the complete Icy toolkit. Download the set at:

      http://naif.jpl.nasa.gov/naif/tutorials.html

Top

Text kernels

Several workbooks use SPICE text kernels. SPICE identifies a text kernel as an ASCII text file containing the mark-up tags the kernel subsystem requires to identify data assignments in that file, and "name=value" data assignments.

The subsystem uses two tags:

      \begintext

      \begindata

Things to know:

1. The \begindata tag marks the start of a data definition block. The subsystem processes all text following this marker as SPICE kernel data assignments until finding a \begintext marker.

2. The kernel subsystem defaults to the \begintext mode until the parser encounters a \begindata tag. Once in \begindata mode the subsystem processes all text as variable assignments until the next \begintext tag.

3. Enter the tags as the only text on a line, i.e.:

 
      \begintext
 
         ... commentary information on the data assignments ...
 
      \begindata
 
         ... data assignments ...
 

4. CSPICE delivery N0059 added to the CSPICE and Icy text kernel parsers the functionality to read non native text kernels, i.e. a Unix compiled library can read a MS Windows native text kernel, a MS Windows compiled library can read a Unix native text kernel. Mice acquires this capability from CSPICE.

5. With regards to the FORTRAN distribution, as of delivery N0057 the FURNSH call includes a line terminator check, signaling an error on any attempt to read non-native text kernels.

Top

Text kernel format

Scalar assignments.

      VAR_NAME_DP  = 1.234
      VAR_NAME_INT = 1234
      VAR_NAME_STR = 'FORBIN'

Vector assignments. Vectors must contain the same type data.

      VEC_NAME_DP  = ( 1.234   , 45.678  , 901234.5 )
      VEC_NAME_INT = ( 1234    , 456     , 789      )
      VEC_NAME_STR = ( 'FORBIN', 'FALKEN', 'ROBUR'  )
 
      also
 
      VEC_NAME_DP  = ( 1.234,
                      45.678,
                      901234.5 )
 
      VEC_NAME_STR = ( 'FORBIN',
                       'FALKEN',
                       'ROBUR' )

      TIME_VAL = @31-JAN-2003-12:34:56.798
      TIME_VEC = ( @01-DEC-2004, @15-MAR-2004 )

The above examples depict direct assignments via the '=' operator. The kernel pool also permits incremental assignments via the '+=' operator.

Please refer to the kernels required reading, kernel.req, for additional information.

Top

Kernels for lessons

Top

Input kernel files

The following kernels are used in examples provided in these lessons:

      FILE NAME                TYPE  DESCRIPTION
      -----------------------  ----  ----------------------
      naif0008.tls             LSK   Generic LSK
      leapseconds.tls          LSK   The current leapseconds
                                     kernel (naif0008.tls as
                                     of Jan 2006)
      de405s.bsp               SPK   Planet Ephemeris SPK
      pck00008.tpc             PCK   Generic PCK

   ftp://naif.jpl.nasa.gov/pub/naif/toolkit_docs/Lessons/

Top

Output

The code examples listed in this workbook include corresponding outputs for the described inputs. The output of a given example on a particular platform may not exactly match that shown since compilers and math libraries differ between platform architectures.

Top

Lesson 1: Kernel Management with the Kernel Subsystem

Lesson Goals:

This lesson demonstrates use of the kernel subsystem to load, unload, and list loaded kernels.

This lesson requires creation of a SPICE meta kernel.

Top

Relevant Routines

-- cspice_furnsh loads the meta kernel and the SPICE kernels listed within that kernel.

-- cspice_ktotal retrieves the number of SPICE kernels loaded by the kernel subsystem.

-- cspice_kdata returns information about each loaded kernel.

-- cspice_unload removes a kernel and deletes any pool variables defined by that kernel from the kernel subsystem.

-- cspice_kclear deletes all kernel pool data from the kernel subsystem.

Top

Requirements and References

Knowledge of information in the kernels.req document, the mk.ppt and intro_to_kernels.ppt tutorial files.

Top

Programming Task

Write a program to load a meta kernel, interrogate the Icy system for the names and types of all loaded kernels, then demonstrate the unload functionality and the resulting effects.

Top

Code Solution

Top

First, create a meta text kernel:

You can use two versions of a meta kernel with code examples (meta.tm) in this lesson. Either a kernel with explicit path information:

 
   \begindata
 
      KERNELS_TO_LOAD = ( 'kernels/spk/de405s.bsp',
                          'kernels/pck/pck00008.tpc',
                          'kernels/lsk/leapseconds.tls')
 
   \begintext
 

 
   \begintext
 
   Define the paths to the kernel directory. Use the PATH_SYMBOLS
   as aliases to the paths.
 
   \begindata
 
      PATH_VALUES     = ( 'kernels/lsk',
                          'kernels/spk',
                          'kernels/pck' )
 
      PATH_SYMBOLS    = ( 'LSK', 'SPK', 'PCK' )
 
      KERNELS_TO_LOAD = ( '$LSK/naif0008.tls',
                          '$SPK/de405s.bsp',
                          '$PCK/pck00008.tpc' )
 
   \begintext
 

Top

Now the solution source code:

 
   PRO KERNEL
 
      ;;
      ;; Assign the path name of the meta kernel to META.
      ;;
      META = 'meta.tm'
 
      ;;
      ;; Load the meta kernel then use KTOTAL to interrogate the SPICE
      ;; kernel subsystem.
      ;;
      cspice_furnsh, META
      cspice_ktotal, 'ALL', count
      print, 'Kernel count after load: ', count
 
      ;;
      ;; Loop over the number of files; interrogate the SPICE system
      ;; with kdata_c for the kernel names and the type. 'found'
      ;; returns a boolean indicating whether any kernel files of
      ;; the specified type were loaded by the kernel subsystem.
      ;; This example ignores checking 'found' as kernels are known
      ;; to be loaded.
      ;;
      for i = 0, (count-1)  do begin
         cspice_kdata, i, 'ALL', file, type, source, handle, found
         print, 'File   ' + file
         print, 'Type   ' + type
         print, 'Source ' + source
         print
      endfor
 
      ;;
      ;; Unload one kernel then check the count.
      ;;
      cspice_unload, 'kernels/spk/de405s.bsp'
      cspice_ktotal, 'ALL', count
 
      ;;
      ;; The subsystem should report one less kernel.
      ;;
      print, 'Kernel count after one unload : ', count
 
      ;;
      ;; Now unload the meta kernel. This action unloads all
      ;; files listed in the meta kernel.
      ;;
      cspice_unload, META
 
      ;;
      ;; Check the count. Icy should return a count of zero.
      ;;
      cspice_ktotal, 'ALL', count
      print, 'Kernel count after meta unload: ', count
 
   END
 

Top

Run the code example

First we see the number of all loaded kernels returned from the cspice_ktotal call:

 
    Kernel count after load:   4
 

 
   File   meta.tm
   Type   META
   Source
 
   File   kernels/spk/de405s.bsp
   Type   SPK
   Source meta.tm
 
   File   kernels/pck/pck00008.tpc
   Type   TEXT
   Source meta.tm
 
   File   kernels/lsk/naif0008.tls
   Type   TEXT
   Source meta.tm
 
   Kernel count after one unload :   3
   Kernel count after meta unload:   0
 

Top

Lesson 2: The Kernel Pool

Lesson Goals:

The lesson demonstrates the Icy system's facility to retrieve different types of data (string, numeric, scalar, array) from the kernel pool.

For the code examples, use this generic text kernel (cassini.tm) containing PCK-type data, kernels to load, and example time strings:

   \begintext
 
   Ring model data.
 
   \begindata
 
      BODY699_RING1_NAME     = 'A Ring'
      BODY699_RING1          = (122170.0 136780.0 0.1 0.1 0.5)
 
      BODY699_RING1_1_NAME   = 'Encke Gap'
      BODY699_RING1_1        = (133405.0 133730.0 0.0 0.0 0.0)
 
      BODY699_RING2_NAME     = 'Cassini Division'
      BODY699_RING2          = (117580.0 122170.0 0.0 0.0 0.0)
 
   \begintext
 
   The kernel pool recognizes values preceded by '@' as time
   values. When read, the kernel subsystem converts these
   representations into double precision ephemeris time.
 
   Caution: The kernel subsystem interprets the time strings
   identified by '@' as TDB. The same string passed as input
   to @STR2ET is processed as UTC.
 
   The three expressions stored in the EXAMPLE_TIMES array represent
   the same epoch.
 
   \begindata
 
      EXAMPLE_TIMES       = ( @APRIL-1-2004-12:34:56.789,
                              @4/1/2004-12:34:56.789,
                              @JD2453097.0242684
                             )
 
   \begintext
 
   Name the kernels to load. Use path symbols.
 
   \begindata
 
      PATH_VALUES     = ('kernels/spk',
                         'kernels/pck',
                         'kernels/lsk')
 
      PATH_SYMBOLS    = ('SPK' , 'PCK' , 'LSK' )
 
      KERNELS_TO_LOAD = ( '$SPK/de405s.bsp',
                          '$PCK/pck00008.tpc',
                          '$LSK/leapseconds.tls')
 
   \begintext

Top

Relevant Routines

-- cspice_gipool retrieves integer values from the kernel subsystem.

-- cspice_gdpool retrieves double precision values from the kernel subsystem

-- cspice_gcpool retrieves character values from the kernel subsystem

-- cspice_dtpool returns data (name, type, size) describing a kernel pool variable.

-- cspice_gnpool retrieves the names of kernel pool variables matching a given template.

Top

Requirements and References

Knowledge of the material in the kernels.req document and the intro_to_kernels.ppt tutorial file.

The main references for pool routines are found in the API documentation for the particular routines.

Top

Programming Task

Write a program to retrieve particular string and numeric text kernel variables, both scalars and arrays. Interrogate the kernel pool for assigned variable names.

Top

Code Solution

 
   PRO KERVAR
 
      ;;
      ;; Define the max number of kernel variables
      ;; of concern for this examples.
      ;;
      N_ITEMS =  20
 
      ;;
      ;; Define the maximum length for any string. 80 characters,
      ;; plus on for the C null terminator.
      ;;
      STRLEN  = 81
 
      ;;
      ;; Load the example kernel containing the kernel variables.
      ;; The kernels defined in KERNELS_TO_LOAD load into the
      ;; kernel pool with this call.
      ;;
      cspice_furnsh, 'cassini.tm'
 
      ;;
      ;; Initialize the start value. This values indicates
      ;; index of the first element to return if a kernel
      ;; variable is an array. START = 0 indicates return everything.
      ;; START = 1 indicates return everything but the first element.
      ;;
      START = 0;
 
      ;;
      ;; Set the template for the variable names to find. Let's
      ;; look for all variables containing  the string RING.
      ;; Define this with the wildcard template '*RING*'. Note:
      ;; the template '*RING' would match any variable name
      ;; ending with the RING string.
      ;;
      tmplate = '*RING*'
 
      ;;
      ;; We're ready to interrogate the kernel pool for the
      ;; variables matching the template. cspice_gnpool tells us:
      ;;
      ;;  1. Does the kernel pool contain any variables that
      ;;     match the template (value of found).
      ;;  2. If so, how many variables?
      ;;  3. The variable names. (cvals, an array of strings)
      ;;
 
      cspice_gnpool, tmplate, START, N_ITEMS, STRLEN, cvals, found
 
      if ( found) then begin
         print, 'No. variables matching template: ', n_elements(cvals)
      endif else begin
         print, 'No kernel variables matched template'
      stop
      endelse
 
      ;;
      ;; Okay, now we know something about the kernel pool
      ;; variables of interest to us. Let's find out more...
      ;;
      for i=0L, (n_elements(cvals)-1L) do begin
 
         ;;
         ;; Use dtpool to return the dimension and type,
         ;; C (character) or N (numeric), of each pool
         ;; variable name in the cvals array.
         ;;
         cspice_dtpool, cvals[i], found, dim, type
         print, cvals[i]
         print, ' No. items: ' + string(dim) + ' Of type: ' + type
 
         ;;
         ;; Test character equality, 'N' or 'C'.
         ;;
         case type of
 
            'N': begin
 
                  ;;
                  ;; If 'type' equals 'N', we found a numeric array.
                  ;; In this case any numeric array will be an array
                  ;; of double precision numbers ("doubles").
                  ;; cspice_gdpool retrieves doubles from the
                  ;; kernel pool.
                  ;;
                  cspice_gdpool, cvals[i], start, N_ITEMS, dvars, $
                                                           found
 
                  for m=0L, (n_elements(dvars)-1L) do begin
 
                     print, '  Numeric value: ', dvars[m]
 
                  endfor
 
               end
 
            'C': begin
 
                  ;;
                  ;; If 'type' equals 'C', we found a string array.
                  ;; gcpool retrieves string values from the
                  ;; kernel pool.
                  ;;
                  cspice_gcpool, cvals[i], start, N_ITEMS, STRLEN, $
                                                     cvars, found
 
                  for j=0L, (n_elements(cvars)-1L) do begin
 
                     print, '  String value : ', cvars[j]
 
                  endfor
 
         end
 
         endcase
 
         print
 
      endfor
 
      ;;
      ;; Now look at the time variable EXAMPLE_TIMES. Extract this
      ;; value as an array of doubles.
      ;;
      cspice_gdpool, 'EXAMPLE_TIMES', start, N_ITEMS, dvars, found
 
      print, 'EXAMPLE_TIMES'
 
      for j=0L, (n_elements(dvars)-1L) do begin
 
         print, FORMAT='(A14,F24.6)', '  Time value: ', dvars[j]
 
      endfor
 
      ;;
      ;; Done. Unload the kernels.
      ;;
      cspice_kclear
 
   END
 

Top

Run the code example

The program runs and first reports the number of kernel pool variables matching the template, 6.

 
   No. variables matching template:   6
 

 
   BODY699_RING1
    No. items:            5 Of type: N
     Numeric value:        122170.00
     Numeric value:        136780.00
     Numeric value:       0.10000000
     Numeric value:       0.10000000
     Numeric value:       0.50000000
 
   BODY699_RING2
    No. items:            5 Of type: N
     Numeric value:        117580.00
     Numeric value:        122170.00
     Numeric value:        0.0000000
     Numeric value:        0.0000000
     Numeric value:        0.0000000
 
   BODY699_RING1_1
    No. items:            5 Of type: N
     Numeric value:        133405.00
     Numeric value:        133730.00
     Numeric value:        0.0000000
     Numeric value:        0.0000000
     Numeric value:        0.0000000
 
   BODY699_RING1_NAME
    No. items:            1 Of type: C
     String value : A Ring
 
   BODY699_RING2_NAME
    No. items:            1 Of type: C
     String value : Cassini Division
 
   BODY699_RING1_1_NAME
    No. items:            1 Of type: C
     String value : Encke Gap
 

 
   EXAMPLE_TIMES
     Time value:         134094896.789000
     Time value:         134094896.789000
     Time value:         134094896.789753
 

Top

Lesson 3: Coordinate Conversions

Lesson Goals:

The Icy system provides functions to convert coordinate tuples between Cartesian and various non Cartesian coordinate systems including conversion between geodetic and rectangular coordinates.

This lesson presents these coordinate transform routines for rectangular, cylindrical, and spherical systems.

Top

Relevant Routines

-- cspice_latrec, latitudinal to rectangular

-- cspice_latcyl, latitudinal to cylindrical

-- cspice_latsph, latitudinal to spherical

-- cspice_reccyl, rectangular to cylindrical

-- cspice_recgeo, rectangular to geodetic

-- cspice_reclat, rectangular to latitudinal

-- cspice_recsph, rectangular to spherical

-- cspice_recrad, rectangular to right ascension - declination

-- cspice_sphrec, spherical to rectangular

-- cspice_sphcyl, spherical to cylindrical

-- cspice_sphlat, spherical to latitudinal

-- cspice_cyllat, cylindrical to latitudinal

-- cspice_cylsph, cylindrical to spherical

-- cspice_cylrec, cylindrical to rectangular

-- cspice_georec, geodetic to rectangular

Top

Requirements and References

Basic knowledge of the standard coordinate systems used in celestial mechanics. The contents of concepts.ppt and derived_quant.ppt tutorial files.

Top

Programming Task

Write a program to convert a Cartesian 3-vector representing some location to the other coordinate representations. Use the position of the Moon with respect to Earth in an inertial and non-inertial reference frame as the example vector.

Top

Code Solution

 
   PRO COORD
 
      ;;
      ;; Define the inertial and non inertial frame names.
      ;;
      ;; Initialize variables or set type. All variables
      ;; used in a PROMPT construct must be initialized
      ;; as strings.
      ;;
      INRFRM = 'J2000'
      NONFRM = 'IAU_EARTH'
      timstr = ''
 
      ;;
      ;; Load the needed kernels using a cspice_furnsh call on the
      ;; meta kernel.
      ;;
      cspice_furnsh, 'meta.tm'
 
      ;;
      ;; Prompt the user for a time string. Convert the
      ;; time string to ephemeris time J2000 (ET).
      ;;
      read, timstr, PROMPT = 'Time of interest: '
      cspice_str2et,  timstr, et
 
      ;;
      ;; Access the kernel pool data for the triaxial radii of the
      ;; Earth, 'rad[0]' holds the equatorial radius, 'rad[2]'
      ;; the polar radius.
      ;;
      cspice_bodvrd, 'EARTH', 'RADII', 3, rad
 
      ;;
      ;; Calculate the flattening factor for the Earth.
      ;;
      ;;          equatorial_radius - polar_radius
      ;; flat =   ________________________________
      ;;
      ;;                equatorial_radius
      ;;
      flat = (rad[0] - rad[2])/rad[0];
 
      ;;
      ;; Make the cspice_spkpos call to determine the apparent
      ;; position of the Moon w.r.t. to the Earth at 'et' in the
      ;; inertial frame.
      ;;
      cspice_spkpos,  'MOON', et, INRFRM, 'LT+S','EARTH', pos, ltime
 
      ;;
      ;; Show the current frame and time.
      ;;
      print, ' Time : '         , timstr
      print, '  Inertial Frame: ', inrfrm
 
      ;;
      ;; First convert the position vector
      ;; X = pos[0], Y = pos[1], Z = pos[2], to RA/DEC.
      ;;
      cspice_recrad,  pos, range, ra, dec
      print, '   Range/Ra/Dec'
      print, '    Range: ', range
      print, '    RA   : ', ra * cspice_dpr()
      print, '    DEC  : ', dec* cspice_dpr()
 
      ;;
      ;; ...latitudinal coordinates...
      ;;
      cspice_reclat,  pos, range, lon, lat
      print, '   Latitudinal'
      print, '    Rad  : ', range
      print, '    Lon  : ', lon * cspice_dpr()
      print, '    Lat  : ', lat * cspice_dpr()
 
      ;;
      ;; ...spherical coordinates use the colatitude,
      ;; the angle from the Z axis.
      ;;
      cspice_recsph,  pos, range, colat, lon
      print, '   Spherical'
      print, '    Rad  : ', range
      print, '    Lon  : ', lon   * cspice_dpr()
      print, '    Colat: ', colat * cspice_dpr()
 
 
      ;;
      ;; Make the cspice_spkpos call to determine the apparent
      ;; position of the Moon w.r.t. to the Earth at 'et' in the
      ;; non-inertial, body fixed, frame.
      ;;
      cspice_spkpos,  'MOON', et, nonfrm, 'LT+S','EARTH', pos, ltime
 
      print
      print, '  Non-inertial Frame: ' + nonfrm
 
      ;;
      ;; ...latitudinal coordinates...
      ;;
      cspice_reclat,  pos, range, lon, lat
      print, '   Latitudinal '
      print, '    Rad  : ', range
      print, '    Lon  : ', lon * cspice_dpr()
      print, '    Lat  : ', lat * cspice_dpr()
 
      ;;
      ;; ...spherical coordinates...
      ;;
      cspice_recsph,  pos, range, colat, lon
      print, '   Spherical'
      print, '    Rad  : ', range
      print, '    Lon  : ', lon   * cspice_dpr()
      print, '    Colat: ', colat * cspice_dpr()
 
      ;;
      ;; ...finally, convert the position to geodetic coordinates.
      ;;
      cspice_recgeo,  pos, rad[0], flat, lon, lat, range
      print, '   Geodetic'
      print, '    Rad  : ', range
      print, '    Lon  : ', lon * cspice_dpr()
      print, '    Lat  : ', lat * cspice_dpr()
      print
 
   END
 

Top

Run the code example

Input a time/date at which to calculate the Moon's position. (the 'TDB' tag indicates a Barycentric Dynamical Time value).

 
   Time of interest: Feb 3 2002 TDB
 

 
    Time : Feb 3 2002 TDB
     Inertial Frame: J2000
 

 
      Range/Ra/Dec
       Range:        369340.82
       RA   :        203.64369
       DEC  :       -4.9790104
 

 
      Latitudinal
       Rad  :        369340.82
       Lon  :       -156.35631
       Lat  :       -4.9790104
 

 
      Spherical
       Rad  :        369340.82
       Lon  :       -156.35631
       Colat:        94.979010
 

     Non-inertial Frame: IAU_EARTH

 
      Latitudinal
       Rad  :        369340.82
       Lon  :        70.986950
       Lat  :       -4.9896751
 

 
      Spherical
       Rad  :        369340.82
       Lon  :        70.986950
       Colat:        94.989675
 

 
      Geodetic
       Rad  :        362962.84
       Lon  :        70.986950
       Lat  :       -4.9902493
 

Top

Lesson 4: Advanced Time Manipulation Routines

Lesson Goals:

Introduce the routines used for advanced manipulation of time strings. Understand the concept of ephemeris time (ET) as used in Icy.

Top

Relevant Routines

-- cspice_str2et converts time strings to ephemeris time (ET).

-- cspice_timout formats a time string output.

-- cspice_tpictr creates a format template for use in cspice_timout.

-- cspice_tsetyr sets the reference century/year for two digit representation of the year.

Top

Requirements and References

Knowledge of the time.req document, the time.ppt, lsk_and_sclk.ppt, and other_functions.ppt tutorial files.

Also, examine the header of cspice_timout for a list of the string markers used by cspice_timout and cspice_tpictr to describe time string format. Always keep in mind cspice_str2et assumes 'UTC' unless indicated otherwise.

Top

Programming Task

Demonstrate the advanced functions of the time utilities with regard to formatting of time strings for output. Formatting options include altering calendar representations of the time strings. Convert time-date strings between different Icy-supported formats.

Top

Code Solution

Caution: Be sure to assign sufficient string lengths for time formats/pictures.

 
   PRO TIC
 
      ;;
      ;; Assign the LSK variable to the name of the leapsecond,
      ;; kernel and create an arbitrary time string.
      ;;
      ;; Define the maximum length for any string, 80
      ;; characters plus one null terminator for C.
      ;;
      CALSTR   = 'Mar 15, 2003 12:34:56.789 AM PST';
      LSK      = 'kernels/lsk/leapseconds.tls';
      AMBIGSTR = 'Mar 15, 79 12:34:56';
      STRLEN   = 81
 
      ;;
      ;; Load the leapseconds kernel.
      ;;
      cspice_furnsh, LSK
      print, 'Original time string       : ' + CALSTR
 
      ;;
      ;; Convert the time string to the number of ephemeris
      ;; seconds past the J2000 epoch. This is the most common
      ;; internal time representation used by the CSPICE
      ;; system; CSPICE refers to this as ephemeris time (ET).
      ;;
      cspice_str2et, CALSTR, et
      print, 'Corresponding ET           : ', et
 
      ;;
      ;; Make a picture of an output format. Describe a Unix-like
      ;; time string then send the picture and the 'et' value through
      ;; cspice_timout to format and convert the ET representation
      ;; of the time string into the form described in cspice_timout.
      ;; The '::UTC-7' token indicates the time zone for the 'timstr'
      ;; output - PDT. 'PDT' is part of the output, but not a time
      ;; system token.
 
      ;;
      cspice_timout, et, 'Wkd Mon DD HR:MN:SC PDT YYYY ::UTC-7', $
                                                    STRLEN, timstr
      print, 'Time in string format 1    : ' + timstr
 
      ;;
      ;; Create another picture, this time combine a calendar,
      ;; 2 digit year , with Julian Day format.
      ;;
      cspice_timout, et,                                     $
        'Wkd Mon DD HR:MN ::UTC-7 YR (JULIAND.##### JDUTC)', $
         STRLEN, timstr
      print, 'Time in string format 2    : ' + timstr
 
      ;;
      ;; Why create a picture by hand when Icy can do it for you?
      ;; Input a string to cspice_tpictr with the format of interest.
      ;; 'ok' returns a boolean indicating whether an error occurred
      ;; while parsing the picture string, if so, an error diagnostic
      ;; message returns in 'error'. In this example the picture
      ;; string is known as correct.
      ;;
      cspice_tpictr, '12:34:56.789 P.M. PDT January 1, 2006', $
                      STRLEN, pictr, ok, error
 
 
      ;;
      ;; Confirm the tpictr_c call succeeded. Report the error string
      ;; if not.
      ;;
      if ( ~ok ) then begin
         print, 'ERROR from cspice_tpictr: ' + error
         stop
      endif
 
      cspice_timout, et, pictr, STRLEN, timstr
      print, 'Time in string format 3    : ' + timstr
 
      ;;
      ;; Two digit year representations often cause problems due to
      ;; the ambiguity of the century. The routine cspice_tsetyr gives
      ;; the user the ability to set a default range for 2 digit year
      ;; representation. SPICE uses 1969AD as the default start
      ;; year so the numbers inclusive of 69 to 99 represent years
      ;; 1969AD to 1999AD, the numbers inclusive of 00 to 68 represent
      ;; years 2000AD to 2068AD.
      ;;
      ;; The defined time string 'AMBIGSTR' contains a two-digit
      ;; year. Since the SPICE base year is 1969, the time subsystem
      ;; interprets the string as 1979.
      ;;
      cspice_str2et, AMBIGSTR, et1
 
      ;;
      ;; Set 1980 as the base year causes SPICE to interpret the
      ;; time string's "79" as 2079.
      ;;
      cspice_tsetyr, 1980
      cspice_str2et, AMBIGSTR, et2
 
      ;;
      ;; Calculate the number of years between the two ET
      ;; representations, ~100.
      ;;
      print, 'Years between evaluations  :  ', $
                      (et2 - et1)/cspice_jyear()
 
      ;;
      ;; Reset the default year to 1969.
      ;;
      cspice_tsetyr, 1969
 
      ;;
      ;; Done. Unload the kernels.
      ;;
      cspice_kclear
 
   END
 

Top

Run the code example

 
   Original time string      : Mar 15, 2003 12:34:56.789 AM PST
   Corresponding ET          :    1.0098936e+08
   Time in string format 1   : Sat Mar 15 01:34:56 PDT 2003
   Time in string format 2   : Sat Mar 15 01:34 03 (2452713.85760 JDUTC)
   Time in string format 3   : 01:34:56.789 A.M. PDT March 15, 2003
   Years between evaluations :         100.00000
 

Top

Lesson 5: Error Handling

Lesson Goal:

The Icy error subsystem differs from CSPICE and SPICELIB packages in that the user cannot alter the state of the error subsystem, rather the user can respond to an error signal using the "catch" function. This function natively receives and processes any SPICE error signaled from Icy. The user can therefore "catch" an error signal so as to respond in an appropriate manner.

Top

Relevant Routines:

-- "catch" sets an IDL error handler flagging an error signal in the current procedure. The mechanism operates like setjump/longjump, or catch/throw.

-- "catch, \cancel" cancels an IDL error handler.

Top

Requirements and References

Knowledge of material in the error.req document and the exceptions.ppt tutorial file. Comprehension of the catch/throw concept.

Top

Programming Task

Write an interactive program to return a state vector based on a user's input. Code the program with the capability to recover from user input mistakes, inform the user of the mistake, then continue to run.

Top

Code Solution

 
   PRO ADERR
 
      ;;
      ;; Set initial parameters.
      ;;
      SPICETRUE = 1B
      SPICEFALSE= 0B
      doloop    = SPICETRUE;
 
      ;;
      ;; Load the data we need for state evaluation.
      ;;
      cspice_furnsh, 'meta.tm'
 
      ;;
      ;; Start our input query loop to the user.
      ;;
      while (doloop) do begin
 
         ;;
         ;; Initialize the input value as a string. YOU MUST
         ;; do this to use PROMPT in a read.
         ;;
         targ = ''
 
         ;;
         ;; For simplicity, we request only one input.
         ;; The program calculates the state vector from
         ;; Earth to the user specified target 'targ' in the
         ;; J2000 frame, at ephemeris time zero, using
         ;; aberration correction LT+S (light time plus
         ;; stellar aberration).
         ;;
         read, targ, PROMPT= 'Target: '
 
         if cspice_eqstr( targ, 'NONE') then begin
 
            ;;
            ;; An exit condition. If the user inputs NONE
            ;; for a target name, set the loop to stop...
            ;;
            doloop = SPICEFALSE;
 
         endif else begin
 
            ;;
            ;; ...otherwise evaluate the state between the Earth
            ;; and the target. Initialize an error handler.
            ;;
            catch, err
 
            ;;
            ;; What if the program can't perform the evaluation?
            ;; Then ICY sets an error message informing
            ;; the user of the problem's cause.
            ;;
            ;; Examine the value of 'err' to determine if we
            ;; output a state vector or not.
            ;;
            if ( err ne 0 ) then begin
 
               ;;
               ;; Error signal detected. Output the error response
               ;; information.
               ;;
               print, !error_state.name
               print, !error_state.msg
               print
 
            endif else begin
 
               ;;
               ;; Perform the state lookup. If an error occurs,
               ;; program flow returns the first line after the
               ;; "catch, err"; in that case, 'err' will have a
               ;; non-zero value.
               ;;
               cspice_spkezr, targ, 0.d, 'J2000', 'LT+S', 'EARTH', $
                              state, ltime
 
               ;;
               ;; No error, output the state.
               ;;
               print, FORMAT = '( "R : ", 3F17.5)', state[0:2]
               print, FORMAT = '( "V : ", 3F17.5)', state[3:5]
               print, 'LT: ', ltime
               print
 
            endelse
 
           catch, /cancel
 
         endelse
 
      endwhile
 
      ;;
      ;; Done. Unload the kernels.
      ;;
      cspice_kclear
 
   END
 

Top

Run the code example

Now run the code with various inputs to observe behavior. Begin the run using known astronomical bodies. Recall the Icy default units are kilometers, kilometers per second, kilograms, and seconds. The 'R' marker identifies the (X,Y,Z) position of the body in kilometers, the 'V' marker identifies the velocity of the body in kilometers per second, and the 'LT' marker identifies the one-way light time between the bodies at the requested evaluation time.

 
   Target: Moon
   R :     -291584.61659    -266693.40236     -76095.64756
   V :           0.64353         -0.66608         -0.30132
   LT:        1.3423106
 
   Target: Mars
   R :   234536077.41914 -132584383.59557  -63102685.70619
   V :          30.95976         28.93646         13.11449
   LT:        923.00108
 
   Target: Pluto barycenter
   R : -1451304742.83853-4318174144.40632 -918251433.58736
   V :          35.03838          3.06560         -0.01514
   LT:        15501.258
 
   Target: Puck
   ICY_M_SPICE_ERROR
   CSPICE_SPKEZR: SPICE(SPKINSUFFDATA): [spkezr_c->SPKEZR->SPKEZ->
        SPKAPP->SPKSSB->SPKGEO] Insufficient ephemeris
        data has been loaded to compute the state of
        715 (PUCK) relative to 0 (SOLAR SYSTEM BARYCENTER)
        at the ephemeris epoch 2000 JAN 01 12:00:00.000.
 

The kernel files named in meta.tm did not include ephemeris data for Puck. When the SPK subsystem tried to evaluate Puck's position, the evaluation failed due to lack of data, so an error signaled.

The above error signifies an absence of state information at ephemeris time 2000 JAN 01 12:00:00.000 (the requested time, ephemeris time zero).

Try another look-up.

 
   Target: Casper
   ICY_M_SPICE_ERROR
   CSPICE_SPKEZR: SPICE(IDCODENOTFOUND): [spkezr_c->SPKEZR] The target,
                  'Casper', is not a recognized name for an ephemeris
                   object. The cause of this problem may be that you
                   need an updated version of the SPICE Toolkit.
                   Alternatively you may call SPKEZ directly if you
                   know the SPICE ID codes for both 'Casper'
                   and 'EARTH'
 

Another look-up, this time, something easy.

 
   Target: Venus
   R :   -80970027.54053 -139655772.57390  -53860125.95820
   V :          31.16969        -27.00018        -12.31622
   LT:        567.65507
 

Top

Lesson 6: Windows, and Cells

Lesson Goal:

This lesson introduces the concepts of the SPICE data types 'cell' and 'window'. A 'cell' is a data structure designed to provide easy and safe manipulation of typed array data.

An IDL SPICE cell consists of an IDL structure comprised of the same fields as a C SPICE cell.

A user should create cells by use of the appropriate Icy calls. NAIF recommends against manual creation of cells.

A 'window' is a type of cell containing ordered, double precision values describing a collection of zero or more intervals.

We define an interval, 'i', as all double precision values bounded by and including an ordered pair of numbers,

      [ a , b ]
         i   i

      a    <   b
       i   -    i

      b  <  a
       i     i+1

Top

Relevant Routines

-- cspice_celld, create a cell for double precision data

-- cspice_wncomd determines the compliment of a window with respect to a defined interval.

-- cspice_wncond contracts a window's intervals.

-- cspice_wndifd : Calculate the difference between two windows; i.e. every point existing in the first but not the second.

-- cspice_wnelmd returns TRUE or FALSE if a value exists in a window.

-- cspice_wnexpd expands the size of the intervals in a window.

-- cspice_wnextd extracts a window's endpoints .

-- cspice_wnfetd retrieves a specified interval from a window.

-- cspice_wnfild fills gaps between intervals in a window.

-- cspice_wnfltd filter/removes small intervals from a window.

-- cspice_wnincd determines if an interval exists within a window.

-- cspice_wninsd inserts an interval into a window.

-- cspice_wnintd calculates the intersection of two windows.

-- cspice_wnreld compares two windows. Comparison operations available, equality '=', inequality '<>', subset '<=' and '>=', proper subset '<' and '>'.

-- cspice_wnsumd creates a window summary.

-- cspice_wnunid calculates the union of two windows.

-- cspice_wnvald validates/creates a window from a cell array.

Top

Requirements and References

Knowledge of cells.req, and windows.req documents, as well as the other_functions.ppt tutorial file.

Top

Programming task:

Given the times of line-of-sight for a vehicle from a ground station and the times for an acceptable Sun-station-vehicle phase angle, write a program to determine the time intervals common to both configurations.

Top

Code Solution

 
   PRO WIN
 
      ;;
      ;; Define the cells to use as windows.
      ;; The windows can hold 8 data values i.e.
      ;; four intervals.
      ;;
      MAXSIZ = 8
      loswin = cspice_celld( MAXSIZ )
      phswin = cspice_celld( MAXSIZ )
      sched  = cspice_celld( MAXSIZ )
 
      ;;
      ;; Define a set of time intervals. For the purposes of this
      ;; tutorial program, define time intervals representing
      ;; an unobscured line of sight between a ground station
      ;; and some body.
      ;;
      los = [ 'Jan 1, 2003 22:15:02', 'Jan 2, 2003  4:43:29',  $
              'Jan 4, 2003  9:55:30', 'Jan 4, 2003 11:26:52',  $
              'Jan 5, 2003 11:09:17', 'Jan 5, 2003 13:00:41',  $
              'Jan 6, 2003 00:08:13', 'Jan 6, 2003  2:18:01' ]
 
      ;;
      ;; A second set of intervals representing the times for which
      ;; an acceptable phase angle exits between the ground station,
      ;; the body and the Sun.
      ;;
      phase = [ 'Jan 2, 2003 00:03:30', 'Jan 2, 2003 19:00:00', $
                'Jan 3, 2003  8:00:00', 'Jan 3, 2003  9:50:00', $
                'Jan 5, 2003 12:00:00', 'Jan 5, 2003 12:45:00', $
                'Jan 6, 2003 00:30:00', 'Jan 6, 2003 23:00:00' ]
 
      ;;
      ;; Load our meta kernel for the leapseconds data.
      ;;
      cspice_furnsh, 'meta.tm'
 
      ;;
      ;; SPICE windows consist of double precision values; convert
      ;; the string time tags defined in the 'los'and 'phase'
      ;; arrays to double precision ET. Store the double values
      ;; in the 'loswin' and 'phswin' windows.
      ;;
      cspice_str2et, los  , los_et
      cspice_str2et, phase, phs_et
 
      ;;
      ;; Initialize the cells from the double precision arrays,
      ;; then validate the cells as windows.
      ;;
      for i=0L, (MAXSIZ/2L) -1L do begin
            cspice_wninsd, los_et[i*2], los_et[i*2 + 1], loswin
            cspice_wninsd, phs_et[i*2], phs_et[i*2 + 1], phswin
      endfor
 
      cspice_wnvald, MAXSIZ, MAXSIZ, loswin
      cspice_wnvald, MAXSIZ, MAXSIZ, phswin
      cspice_wnvald, MAXSIZ, MAXSIZ, sched
 
 
      ;;
      ;; The issue for consideration, at what times do line of
      ;; sight events coincide with acceptable phase angles?
      ;; Perform the set operation AND on loswin, phswin,
      ;; (the intersection of the time intervals)
      ;; place the results in the window 'sched'.
      ;;
      cspice_wnintd, loswin, phswin, sched
 
      ;;
      ;; Output the results. The number of intervals in 'sched'
      ;; is half the number of data points (the cardinality).
      ;; Use a call to card_c to retrieve the window's cardinality.
      ;;
 
      print
      print, 'No. data values in sched            : ',            $
                                                 cspice_card(sched)
      print, 'Space available for values in sched : ',            $
                                                 cspice_size(sched)
      print
      print, 'Time intervals meeting defined criterion.'
 
      for i=0L, (cspice_card(sched)/2L)-1L do begin
 
         ;;
         ;; Extract from the derived 'sched' the values defining the
         ;; time intervals.
         ;;
         cspice_wnfetd, sched, i, left, right
 
         ;;
         ;; Convert the ET values to UTC for human comprehension.
         ;;
         cspice_et2utc, left , 'C', 3, utcstr_l
         cspice_et2utc, right, 'C', 3, utcstr_r
 
         ;;
         ;; Output the UTC string and the corresponding index
         ;; for the interval.
         ;;
         print, i, ' ', utcstr_l, utcstr_r
 
      endfor
 
 
      ;;
      ;; Summarize the 'sched' window.
      ;;
      cspice_wnsumd, sched, meas, avg, stddev, small, large
 
      print
      print, 'Summary of sched window'
 
      print, 'o Total measure of sched    : ', meas
      print, 'o Average measure of sched  : ', avg
      print, 'o Standard deviation of '
      print, '  the measures in sched     : ', stddev
 
      ;;
      ;; The values for small and large refer to the indexes of the
      ;; values in the window ('sched'). The shortest interval is
      ;;
      ;;      [ sched.base[ sched.data + small]
      ;;        sched.base[ sched.data + small +1]  ];
      ;;
      ;; the longest is
       ;;
      ;;      [ sched.base[ sched.data + large]
      ;;        sched.base[ sched.data + large +1]  ];
      ;;
      ;; Output the interval indexes for the shortest and longest
      ;; intervals. As IDL bases an array index on 0, the interval
      ;; index is half the array index.
      ;;
      print, 'o Index of shortest interval: ', small/2L
      print, 'o Index of longest interval : ', large/2L
 
   END
 

Top

Run the code example

The output window has the name SCHED (schedule).

Output the amount of data held in SCHED compared to the maximum possible amount.

    No. data values in SCHED            :   6
    Space available for values in SCHED :   8

 
   Time intervals meeting defined criterion.
          0 2003 JAN 02 00:03:30.000  2003 JAN 02 04:43:29.000
          1 2003 JAN 05 12:00:00.000  2003 JAN 05 12:45:00.000
          2 2003 JAN 06 00:30:00.000  2003 JAN 06 02:18:01.000
 

 
   Summary of sched window
   o Total measure of sched    :        25980.000
   o Average measure of sched  :        8660.0000
   o Standard deviation of
     the measures in sched     :        5958.5502
   o Index of shortest interval:            1
   o Index of longest interval :            0
 

Top

Lesson 7: Utility and Constants Routines

Lesson Goals:

Icy provides several routines to perform commonly needed tasks. Among these:

-- convert values between unit expressions

-- determine the equality of strings

-- indicate whether a file exists

-- identify the toolkit version

Top

Relevant Routines

-- cspice_convrt converts between measurements units

-- cspice_tkvrsn returns the current version of the toolkit

-- cspice_eqstr returns a boolean describing the equality of two strings. The comparison is case insensitive and ignores spaces.

-- cspice_exists returns a boolean indicating the existence of a file.

-- cspice_clight : velocity of light in a vacuum, kilometers per second

-- cspice_dpr : number of degrees per radian (180/Pi)

-- cspice_rpd : number radians per degree (Pi/180)

-- cspice_spd : number of seconds per day (60*60*24)

-- cspice_b1900 : Julian Date of the epoch Besselian Date 1900.0

-- cspice_b1950 : Julian date of the epoch Besselian Date 1950.0

-- cspice_j1900 : Julian date of 1900 JAN 0.5 this corresponds to calendar date 1899 DEC 31 12:00:00

-- cspice_j1950 : Julian date of 1950 JAN 1.0 this corresponds to calendar date 1950 JAN 01 00:00:00

-- cspice_j2000 : Julian date of 2000 JAN 1.5 (2000 JAN 01 12:00:00)

-- cspice_j2100 : Julian date of 2100 JAN 1.5, this corresponds to calendar date 2100 JAN 01 12:00:00

-- cspice_twopi : double precision value of 2 * Pi

-- cspice_pi : double precision value of Pi

-- cspice_halfpi : double precision value of 0.5 * Pi

-- cspice_jyear : seconds per Julian year (365.25 Julian days)

-- cspice_tyear : seconds per tropical year (approximately the number of seconds from one spring equinox to the next)

Top

Requirements and References

The references used to define or calculate the constants functions are found in the source code file and/or the API reference. Also reference the other_functions.ppt tutorial file.

Top

Programming Task

Write an interactive program to convert values between various units. Demonstrate the flexibility of the unit conversion routine, the string equality function, and show the version ID function.

Top

Code Solution

 
   PRO UNITS
 
      ;;
      ;; Initialize variables. All variables used in a PROMPT
      ;; construct must be initialized as strings.
      ;;
      funits  = ''
      fromstr = ''
      tunits  = ''
 
      ;;
      ;; Display the Toolkit version string with a
      ;; cspice_tkvrsn call.
      ;;
      vers = cspice_tkvrsn( 'TOOLKIT' )
      print, 'Convert demo program compiled against CSPICE Toolkit ' $
             + vers
 
      ;;
      ;; The user first inputs the name of a unit of measure.
      ;; Send the name through TOSTAN for de-aliasing.
      ;;
      read, funits, PROMPT= 'From Units : '
      tostan, funits
 
      ;;
      ;; Input a double precision value to express in a new
      ;; unit format.
      ;;
      read, fromstr, PROMPT = 'From Value : '
      cspice_prsdp, fromstr, fvalue
 
      ;;
      ;; Now the user inputs the name of the output units.
      ;; Again we send the units name through TOSTAN for
      ;; de-aliasing.
      ;;
      read, tunits, PROMPT = 'To Units   : '
      tostan, tunits
 
      cspice_convrt, fvalue, funits, tunits, tvalue
      print,  tvalue, ' ', tunits
 
   END
 
   PRO TOSTAN, alias
 
      ;;
      ;; As a convenience, let's alias a few common terms
      ;; to their appropriate counterpart. Use cspice_eqstr
      ;; to compare strings. The comparison ignores
      ;; letter case and trailing/leading spaces. NOTE: the SWITCH
      ;; statement performs the same function as the multiple
      ;; "if" blocks. SWITCH was not used in order to demonstrate
      ;; the cspice_eqstr call.
      ;;
 
      if ( cspice_eqstr( alias, 'meter') ) then begin
 
            ;;
            ;; First, a 'meter' by any other name is a
            ;; 'METER' and smells as sweet ...
            ;;
            alias = 'METERS'
      endif
 
      if ( cspice_eqstr( alias, 'klicks'    ) OR $
           cspice_eqstr( alias, 'kilometers') OR $
           cspice_eqstr( alias, 'kilometer' )     ) then begin
 
            ;;
            ;; ... 'klicks' and 'KILOMETERS' and 'KILOMETER'
            ;; identifies 'KM'....
            ;;
            alias = 'KM'
      endif
 
      if ( cspice_eqstr( alias, 'secs') ) then begin
 
            ;;
            ;; ... 'secs' to 'SECONDS'.
            ;;
            alias = 'SECONDS'
      endif
 
      if ( cspice_eqstr( alias, 'miles') ) then begin
 
            ;;
            ;; ... and finally 'miles' to 'STATUTE_MILES'.
            ;; Normal people think in statute miles.
            ;; Only sailors think in nautical miles - one
            ;; minute of arc at the equator.
            ;;
            alias = 'STATUTE_MILES'
      endif
 
      ;;
      ;; Much better. Now return. If the input matched
      ;; none of the aliases, this routine did nothing.
      ;;
 
   END
 

Top

Run the code example

Run a few conversions through the application to ensure it works. The intro banner gives us the Toolkit version against which the application was linked:

 
   Convert demo program compiled against CSPICE Toolkit CSPICE_N0060
   From Units : klicks
   From Value : 3
   To Units   : miles
          1.8641136 STATUTE_MILES
 

Legend states Pheidippides ran from the Marathon Plain to Athens. The modern marathon race (inspired by this event) spans 26.2 miles. How far in kilometers?

 
   Convert demo program compiled against CSPICE Toolkit CSPICE_N0060
   From Units : miles
   From Value : 26.2
   To Units   : km
          42.164813 km
 

Top

Programming Task

Write a program to output Icy constants and use those constants to calculate some rudimentary values.

Top

Code Solution

 
   PRO CONST
 
      ;;
      ;; All the function have the same calling sequence:
      ;;
      ;;    VALUE = function_name()
      ;;
      ;;    some_procedure( function_name() )
      ;;
      ;;    print, function_name()
      ;;
      ;; First a simple example using the seconds per day
      ;; constant...
      ;;
      print,   $
      FORMAT = $
      '("Number of (S)econds (P)er (D)ay           : ", F19.12)',$
                                                       cspice_spd()
 
      ;;
      ;; ...then show the value of degrees per radian, 180/Pi...
      ;;
      print,   $
      FORMAT = $
      '("Number of (D)egrees (P)er (R)adian        : ", F19.16)',$
                                                       cspice_dpr()
 
      ;;
      ;; ...and the inverse, radians per degree, Pi/180.
      ;; It is obvious cspice_dpr() equals 1.d/cspice_rpd(), or
      ;; more simply cspice_dpr() * cspice_rpd() equals 1
      ;;
      print,   $
      FORMAT = $
      '("Number of (R)adians (P)er (D)egree        : ", F19.16)',$
                                                       cspice_rpd()
 
      ;;
      ;; What's the value for the astrophysicist's favorite
      ;; physical constant (in a vacuum)?
      ;;
      print,   $
      FORMAT = $
      '("Speed of light in KM per second           : ", F19.12)',$
                                                   cspice_clight()
 
      ;;
      ;; How long (in Julian days) from the J2000 epoch to the
      ;; J2100 epoch?
      ;;
      print, "Number of days between epochs J2000 and     "
      print, $
      FORMAT = $
      '("  J2100                                   : ", F19.12)',$
                                   cspice_j2100() - cspice_j2000()
 
      ;;
      ;; Redo the calculation returning seconds...
      ;;
      print, "Number of seconds between epochs J2000 "
      print,   $
      FORMAT = $
      '("   and J2100                              : ", F19.5)',$
                cspice_spd() * (cspice_j2100() - cspice_j2000() )
 
      ;;
      ;; ...then tropical years.
      ;;
      print,  "Number of tropical years between epochs     "
      print, $
      FORMAT = $
      '("  J2000 and J2100                         : ", F19.12)',$
                              ( cspice_spd() / cspice_tyear() )  $
                           * (cspice_j2100() - cspice_j2000() )
 
      ;;
      ;; Finally, how can I convert a radian value to degrees.
      ;;
      print,   $
      FORMAT = $
      '("Number of degrees in Pi/2 radians of arc  : ", F19.16)',$
                                    cspice_halfpi() * cspice_dpr()
 
      ;;
      ;; and degrees to radians.
      ;;
      print,   $
      FORMAT = $
      '("Number of radians in 250 degrees of arc   : ", F19.16)',$
                                              250.D * cspice_rpd()
 
   END
 

Top

Run the code example

 
   Number of (S)econds (P)er (D)ay           :  86400.000000000000
   Number of (D)egrees (P)er (R)adian        : 57.2957795130823229
   Number of (R)adians (P)er (D)egree        :  0.0174532925199433
   Speed of light in KM per second           : 299792.457999999984
   Number of days between epochs J2000 and
     J2100                                   :  36525.000000000000
   Number of seconds between epochs J2000
      and J2100                              :    3155760000.00000
   Number of tropical years between epochs
     J2000 and J2100                         :    100.002135902909
   Number of degrees in Pi/2 radians of arc  : 90.0000000000000000
   Number of radians in 250 degrees of arc   :  4.3633231299858242