 
Remote Sensing Hands-On Lesson, using MPO (MATLAB)
===========================================================================
 
   March 01, 2023
 
 
Overview
--------------------------------------------------------
 
   In this lesson you will develop a series of simple programs that
   demonstrate the usage of Mice to compute a variety of different
   geometric quantities applicable to experiments carried out by a remote
   sensing instrument flown on an interplanetary spacecraft. This
   particular lesson focuses on a spectrometer flying on the BepiColombo
   MPO spacecraft, but many of the concepts are easily extended and
   generalized to other scenarios.
 
 
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, if not done already by installing
   the lessons package under the Toolkit's ``doc/html'' directory, create a
   subdirectory called ``lessons'' under the ``doc/html'' directory of the
   ``mice/'' tree and copy this document to that subdirectory before
   loading it into a Web browser.
 
 
References
--------------------------------------------------------
 
   This section lists SPICE documents referred to in this lesson.
 
   Of these documents, the ``Tutorials'' contains the highest level
   descriptions with the least number of details while the ``Required
   Reading'' documents contain much more detailed specifications. The most
   complete specifications are provided in the ``API Documentation''.
 
   In some cases the lesson explanations also refer to the information
   provided in the meta-data area of the kernels used in the lesson
   examples. It is especially true in case of the FK and IK files, which
   often contain comprehensive descriptions of the frames, instrument FOVs,
   etc. Since both the FK and IK are text kernels, the information provided
   in them can be viewed using any text editor, while the meta information
   provided in binary kernels---SPKs and CKs---can be viewed using
   ``commnt'' or ``spacit'' utility programs located in ``mice/exe'' of
   Toolkit installation tree.
 
 
Tutorials
 
   The following SPICE tutorials serve as references for the discussions in
   this lesson:
 
      Name              Lesson steps/functions it describes
      ----------------  -----------------------------------------------
      Time              Time Conversion
      SCLK and LSK      Time Conversion
      SPK               Obtaining Ephemeris Data
      Frames            Reference Frames
      Using Frames      Reference Frames
      PCK               Planetary Constants Data
      CK                Spacecraft Orientation Data
      DSK               Detailed Target Shape (Topography) Data
 
   These tutorials are available from the NAIF server at JPL:
 
      http://naif.jpl.nasa.gov/naif/tutorials.html
 
 
Required Readings
 
   The Required Reading documents are provided with the Toolkit and are
   located under the ``mice/doc'' directory in the Mice installation tree.
 
      Name             Lesson steps/functions that it describes
      ---------------  -----------------------------------------
      ck.req           Obtaining spacecraft orientation data
      dsk.req          Obtaining detailed body shape data
      frames.req       Using reference frames
      naif_ids.req     Determining body ID codes
      pck.req          Obtaining planetary constants data
      sclk.req         SCLK time conversion
      spk.req          Obtaining ephemeris data
      time.req         Time conversion
      mice.req         The Mice API
 
 
The Permuted Index
 
   Another useful document distributed with the Toolkit is the permuted
   index. It is located under the ``mice/doc'' directory in the MATLAB
   installation tree.
 
   This text document provides a simple mechanism by which users can
   discover which Mice functions perform functions of interest, as well as
   the names of the source files that contain these functions.
 
 
 
Mice API Documentation
 
   A Mice routine's specification is found in the HTML API documentation
   page located under ``mice/doc/html/mice''.
 
   For example, the document
 
      mice/doc/html/mice/cspice_str2et.html
 
   describes the cspice_str2et routine.
 
 
Kernels Used
--------------------------------------------------------
 
   The following kernels are used in examples provided in this lesson:
 
      1.  Generic LSK:
 
             naif0012.tls
 
      2.  BepiColombo MPO SCLK:
 
             bc_mpo_step_20230117.tsc
 
      3.  Solar System Ephemeris SPK, subsetted to cover only the time
          range of interest:
 
             de432s.bsp
 
      4.  BepiColombo MPO Spacecraft Trajectory SPK, subsetted to cover
          only the time range of interest:
 
             bc_mpo_mlt_50037_20260314_20280529_v05.bsp
 
      5.  BepiColombo MPO FK:
 
             bc_mpo_v32.tf
 
      6.  BepiColombo MPO Spacecraft CK, subsetted to cover only the time
          range of interest:
 
             bc_mpo_sc_slt_50028_20260314_20280529_f20181127_v03.bc
 
      7.  Generic PCK:
 
             pck00011.tpc
 
      8.  Low-resolution Mercury DSK:
 
             mercury_lowres.bds
 
      9.  SIMBIO-SYS IK:
 
             bc_mpo_simbio-sys_v08.ti
 
 
   These SPICE kernels are included in the lesson package.
 
   In addition to these kernels, the extra credit exercises require the
   following kernels:
 
      #  FILE NAME       TYPE DESCRIPTION
      -- --------------- ---- ---------------------------------------------
      10 jup365_2027.bsp SPK  Generic Jovian Satellite Ephemeris SPK
 
   These SPICE kernels are available from the NAIF server at JPL, in the
   ``satellites/a_old_versions'' subdurectory:
 
      https://naif.jpl.nasa.gov/pub/naif/generic_kernels/spk/
 
 
Mice Modules Used
--------------------------------------------------------
 
   This section provides a complete list of the functions and kernels that
   are suggested for usage in each of the exercises in this lesson. (You
   may wish to not look at this list unless/until you ``get stuck'' while
   working on your own.)
 
      CHAPTER EXERCISE   FUNCTIONS      NON-VOID       KERNELS
      ------- ---------  -------------  -------------  ----------
         1    convtm     cspice_furnsh  cspice_str2et  1,2
                         cspice_unload  cspice_etcal
                                        cspice_timout
                                        cspice_sce2s
 
              extra (*)                 cspice_unitim  1,2
                                        cspice_sct2e
                                        cspice_et2utc
                                        cspice_scs2e
 
         2    getsta     cspice_furnsh  cspice_str2et  1,3,4
                         cspice_kclear  cspice_spkezr
                                        cspice_spkpos
                                        cspice_convrt
 
              extra (*)  cspice_unload  cspice_vnorm   1,4,10
 
         3    xform      cspice_furnsh  cspice_str2et  1-7
                         cspice_kclear  cspice_spkezr
                                        cspice_sxform
                                        cspice_spkpos
                                        cspice_pxform
                                        cspice_convrt
                                        cspice_vsep
 
              extra (*)  cspice_unload                 1-7
 
         4    subpts     cspice_furnsh  cspice_str2et  1,3-4,7,8
                         cspice_kclear  cspice_subpnt
                                        cspice_subslr
 
              extra (*)                 cspice_reclat  1,3-4,7,10
                                        cspice_dpr
                                        cspice_bodvrd
                                        cspice_recpgr
 
         5    fovint     cspice_furnsh  cspice_str2et  1-9
                         cspice_unload  cspice_getfvn
                                        cspice_bodn2c
                                        cspice_sincpt
                                        cspice_reclat
                                        cspice_dpr
                                        cspice_illumf
                                        cspice_et2lst
 
 
         (*) Additional APIs and kernels used in Extra Credit tasks.
 
   Refer to the Mice HTML API documentation pages located under
   ``mice/doc/html/mice'' for detailed interface specifications of these
   functions.
 
 
Time Conversion (convtm)
===========================================================================
 
 
Task Statement
--------------------------------------------------------
 
   Write a program that prompts the user for an input UTC time string,
   converts it to the following time systems and output formats:
 
       1.   Ephemeris Time (ET) in seconds past J2000
 
       2.   Calendar Ephemeris Time
 
       3.   Spacecraft Clock Time
 
   and displays the results. Use the program to convert "2027 JAN 05
   02:04:36" UTC into these alternate systems.
 
 
Learning Goals
--------------------------------------------------------
 
   Familiarity with the various time conversion and parsing functions
   available in the Toolkit. Exposure to source code headers and their
   usage in learning to call functions.
 
 
Approach
--------------------------------------------------------
 
   The solution to the problem can be broken down into a series of simple
   steps:
 
       --   Decide which SPICE kernels are necessary. Prepare a meta-kernel
            listing the kernels and load it into the program.
 
       --   Prompt the user for an input UTC time string.
 
       --   Convert the input time string into ephemeris time expressed as
            seconds past J2000 TDB. Display the result.
 
       --   Convert ephemeris time into a calendar format. Display the
            result.
 
       --   Convert ephemeris time into a spacecraft clock string. Display
            the result.
 
   You may find it useful to consult the permuted index, the headers of
   various source modules, and the ``Time Required Reading'' (time.req) and
   ``SCLK Required Reading'' (sclk.req) documents.
 
   When completing the ``calendar format'' step above, consider using one
   of two possible methods: cspice_etcal or cspice_timout.
 
 
Solution
--------------------------------------------------------
 
 
Solution Meta-Kernel
 
   The meta-kernel we created for the solution to this exercise is named
   'convtm.tm'. Its contents follow:
 
      KPL/MK
 
         This is the meta-kernel used in the solution of the ``Time
         Conversion'' task in the Remote Sensing Hands On Lesson.
 
         The names and contents of the kernels referenced by this
         meta-kernel are as follows:
 
            1. Generic LSK:
 
                  naif0012.tls
 
            2. BepiColombo MPO SCLK:
 
                  bc_mpo_step_20230117.tsc
 
 
      \begindata
 
       KERNELS_TO_LOAD = (
 
       'kernels/lsk/naif0012.tls',
       'kernels/sclk/bc_mpo_step_20230117.tsc'
 
                         )
 
      \begintext
 
 
Solution Source Code
 
   A sample solution to the problem follows:
 
      %
      % Remote sensing lesson:  Time conversion
      %
      function convtm()
 
      %
      % Local parameters
      %
      METAKR = 'convtm.tm';
      SCLKID = -121;
 
      %
      % Load the kernels this program requires.
      % Both the spacecraft clock kernel and a
      % leapseconds kernel should be listed in
      % the meta-kernel.
      %
      cspice_furnsh ( METAKR );
 
      %
      % Prompt the user for the input time string.
      %
      utctim = input ( 'Input UTC Time: ', 's' );
 
      fprintf ( 'Converting UTC Time: %s\n', utctim )
 
      %
      % Convert utctim to et.
      %
      et = cspice_str2et ( utctim );
 
      fprintf ( '   ET Seconds Past J2000: %16.3f\n', et )
 
      %
      % Now convert ET to a formal calendar time
      % string.  This can be accomplished in two
      % ways.
      %
      calet = cspice_etcal ( et );
 
      fprintf ( '   Calendar ET (cspice_etcal):  %s\n', calet )
 
      %
      % Or use cspice_timout for finer control over the
      % output format.  The picture below was built
      % by examining the header of cspice_timout.
      %
      calet = cspice_timout ( et, 'YYYY-MON-DDTHR:MN:SC ::TDB' );
 
      fprintf ( '   Calendar ET (cspice_timout): %s\n', calet )
 
      %
      % Convert ET to spacecraft clock time.
      %
      sclkst = cspice_sce2s ( SCLKID, et );
 
      fprintf ( '   Spacecraft Clock Time: %s\n', sclkst )
 
      %
      % Unload kernels we loaded at the start of the function.
      %
      cspice_unload ( METAKR );
 
      %
      % End of function convtm
      %
 
 
Solution Sample Output
 
   Execute the program:
 
      Input UTC Time: 2027 JAN 05 02:04:36
      Converting UTC Time: 2027 JAN 05 02:04:36
         ET Seconds Past J2000:    852386745.184
         Calendar ET (cspice_etcal):  2027 JAN 05 02:05:45.184
         Calendar ET (cspice_timout): 2027-JAN-05T02:05:45
         Spacecraft Clock Time: 1/0863834674:28127
 
 
Extra Credit
--------------------------------------------------------
 
   In this ``extra credit'' section you will be presented with more complex
   tasks, aimed at improving your understanding of time conversions, the
   Toolkit routines that deal with them, and some common errors that may
   happen during the execution of these conversions.
 
   These ``extra credit'' tasks are provided as task statements, and unlike
   the regular tasks, no approach or solution source code is provided. In
   the next section, you will find the numeric solutions (when applicable)
   and answers to the questions asked in these tasks.
 
 
Task statements and questions
 
       1.   Extend your program to convert the input UTC time string to TDB
            Julian Date. Convert "2027 JAN 05 02:04:36" UTC.
 
       2.   Remove the LSK from the original meta-kernel and run your
            program again, using the same inputs as before. Has anything
            changed? Why?
 
       3.   Remove the SCLK from the original meta-kernel and run your
            program again, using the same inputs as before. Has anything
            changed? Why?
 
       4.   Modify your program to perform conversion of UTC or ephemeris
            time, to a spacecraft clock string using the NAIF ID for the
            BepiColombo MPO SIMBIO-SYS HRIC channel. Convert "2027 JAN 05
            02:04:36" UTC.
 
       5.   Find the earliest UTC time that can be converted to BepiColombo
            MPO spacecraft clock.
 
       6.   Extend your program to convert the spacecraft clock time
            obtained in the regular task back to UTC Time and present it in
            ISO calendar date format, with a resolution of milliseconds.
 
       7.   Examine the contents of the generic LSK and the BepiColombo MPO
            SCLK kernels. Can you understand and explain what you see?
 
 
Solutions and answers
 
       1.   Two methods exist in order to convert ephemeris time to Julian
            Date: cspice_unitim and cspice_timout. The difference between
            them is the type of output produced by each method.
            cspice_unitim returns the double precision value of an input
            epoch, while cspice_timout returns the string representation of
            the ephemeris time in Julian Date format (when picture input is
            set to 'JULIAND.######### ::TDB'). Refer to the function header
            for further details. The solution for the requested input UTC
            string is:
 
         Julian Date TDB:   2461410.5873285
 
       2.   When running the original program without the LSK kernel, an
            error is produced:
 
      Error using mice
      SPICE(NOLEAPSECONDS): [str2et_c->STR2ET->TTRANS] The variable that
      points to the leapseconds (DELTET/DELTA_AT) could not be located in
      the kernel pool.  It is likely that the leapseconds kernel has not
      been loaded. (CSPICE_N0067)
 
      Error in cspice_str2et (line 710)
            [et] = mice('str2et_c', timstr);
 
      Error in convtm (line 32)
      et = cspice_str2et ( utctim );
 
 
            This error is triggered by cspice_str2et because the variable
            that points to the leapseconds is not present in the kernel
            pool and therefore the program lacks data required to perform
            the requested UTC to ephemeris time conversion.
 
            By default, SPICE will report, as a minimum, a short
            descriptive message and a expanded form of this short message
            where more details about the error are provided. If this error
            message is not sufficient for you to understand what has
            happened, you could go to the ``Exceptions'' section in the
            SPICELIB or CSPICE headers of the function that has triggered
            the error and find out more information about the possible
            causes.
 
       3.   When running the original program without the SCLK kernel, an
            error is produced:
 
      Error using mice
      SPICE(KERNELVARNOTFOUND): [sce2s_c->SCE2S->SCE2T->SCTYPE->SCTY01]
      Kernel variable SCLK_DATA_TYPE_121 was not found in the kernel pool.
      (CSPICE_N0067)
 
      Error in cspice_sce2s (line 303)
            [sclkch] = mice('sce2s_c',sc, et);
 
      Error in convtm (line 61)
      sclkst = cspice_sce2s ( SCLKID, et );
 
 
            This error is triggered by cspice_sce2s. In this case the error
            message may not give you enough information to understand what
            has actually happened. Nevertheless, the expanded form of this
            short message clearly indicates that the SCLK kernel for the
            spacecraft ID -121 has not been loaded.
 
            The UTC string to ephemeris time conversion and the conversion
            of ephemeris time into a calendar format worked normally as
            these conversions only require the LSK kernel to be loaded.
 
       4.   The first thing you need to do is to find out what the NAIF ID
            is for the SIMBIO-SYS HRIC channel. In order to do so, examine
            the BepiColombo MPO frames definitions kernel listed above and
            look for the ``BepiColombo MPO Mission NAIF ID Codes'' or for
            the ``BepiColombo MPO NAIF ID Codes to Name Mapping'' and
            there, for the NAIF ID given to MPO_SIMBIO-SYS_HRIC_FPA (which
            is -121610). Then replace in your code the SCLK ID -121 with
            -121610. After executing the program using the original
            meta-kernel, you will be getting the same error as in the
            previous task. Despite the error being exactly the same, this
            case is different. Generally, spacecraft clocks are associated
            with the spacecraft ID and not with its payload, sensors or
            structures IDs. Therefore, in order to do conversions from/to
            spacecraft clock for payload, sensors or spacecraft structures,
            the spacecraft ID must be used.
 
            Note that this does not need to be true for all missions or
            payloads, as SPICE does not restrict the SCLKs to spacecraft
            IDs only. Please refer to your mission's SCLK kernels for
            particulars.
 
       5.   Use cspice_sct2e with the encoding of the MPO spacecraft clock
            time set to 0.0 ticks and convert the resulting ephemeris time
            to UTC using either cspice_timout or cspice_et2utc. The
            solution for the requested SCLK string is:
 
         Earliest UTC convertible to SCLK: 1999-08-22T00:00:05.204
 
       6.   Use cspice_scs2e with the SCLK string obtained in the
            computations performed in the regular tasks and convert the
            resulting ephemeris time to UTC using either cspice_et2utc,
            with 'ISOC' format and 3 digits precision, or using
            cspice_timout using the time picture 'YYYY-MM-DDTHR:MN:SC.###
            ::RND'. The solution of the requested conversion is:
 
         Spacecraft Clock Time:          1/0863834674:28127
         UTC time from spacecraft clock: 2027-01-05T02:04:36.000
 
 
Obtaining Target States and Positions (getsta)
===========================================================================
 
 
Task Statement
--------------------------------------------------------
 
   Write a program that prompts the user for an input UTC time string,
   computes the following quantities at that epoch:
 
       1.   The apparent state of Mercury as seen from BepiColombo MPO in
            the J2000 frame, in kilometers and kilometers/second. This
            vector itself is not of any particular interest, but it is a
            useful intermediate quantity in some geometry calculations.
 
       2.   The apparent position of the Earth as seen from BepiColombo MPO
            in the J2000 frame, in kilometers.
 
       3.   The one-way light time between BepiColombo MPO and the apparent
            position of Earth, in seconds.
 
       4.   The apparent position of the Sun as seen from Mercury in the
            J2000 frame (J2000), in kilometers.
 
       5.   The actual (geometric) distance between the Sun and Mercury, in
            astronomical units.
 
   and displays the results. Use the program to compute these quantities at
   "2027 JAN 05 02:04:36" UTC.
 
 
Learning Goals
--------------------------------------------------------
 
   Understand the anatomy of an cspice_spkezr call. Discover the difference
   between cspice_spkezr and cspice_spkpos. Familiarity with the Toolkit
   utility ``brief''. Exposure to unit conversion with Mice.
 
 
Approach
--------------------------------------------------------
 
   The solution to the problem can be broken down into a series of simple
   steps:
 
       --   Decide which SPICE kernels are necessary. Prepare a meta-kernel
            listing the kernels and load it into the program.
 
       --   Prompt the user for an input time string.
 
       --   Convert the input time string into ephemeris time expressed as
            seconds past J2000 TDB.
 
       --   Compute the state of Mercury relative to BepiColombo MPO in the
            J2000 reference frame, corrected for aberrations.
 
       --   Compute the position of Earth relative to BepiColombo MPO in
            the J2000 reference frame, corrected for aberrations. (The
            function in the library that computes this also returns the
            one-way light time between BepiColombo MPO and Earth.)
 
       --   Compute the position of the Sun relative to Mercury in the
            J2000 reference frame, corrected for aberrations.
 
       --   Compute the position of the Sun relative to Mercury without
            correcting for aberration.
 
            Compute the length of this vector. This provides the desired
            distance in kilometers.
 
       --   Convert the distance in kilometers into AU.
 
   You may find it useful to consult the permuted index, the headers of
   various source modules, and the ``SPK Required Reading'' (spk.req)
   document.
 
   When deciding which SPK files to load, the Toolkit utility ``brief'' may
   be of some use.
 
   ``brief'' is located in the ``mice/exe'' directory for MATLAB toolkits.
   Consult its user's guide available in ``mice/doc/brief.ug'' for details.
 
 
Solution
--------------------------------------------------------
 
 
Solution Meta-Kernel
 
   The meta-kernel we created for the solution to this exercise is named
   'getsta.tm'. Its contents follow:
 
      KPL/MK
 
         This is the meta-kernel used in the solution of the
         ``Obtaining Target States and Positions'' task in the
         Remote Sensing Hands On Lesson.
 
         The names and contents of the kernels referenced by this
         meta-kernel are as follows:
 
            1. Generic LSK:
 
                  naif0012.tls
 
            2. Solar System Ephemeris SPK, subsetted to cover only
               the time range of interest:
 
                  de432s.bsp
 
            3. BepiColombo MPO Spacecraft Trajectory SPK, subsetted
               to cover only the time range of interest:
 
                  bc_mpo_mlt_50037_20260314_20280529_v05.bsp
 
 
      \begindata
 
       KERNELS_TO_LOAD = (
 
       'kernels/lsk/naif0012.tls',
       'kernels/spk/de432s.bsp',
       'kernels/spk/bc_mpo_mlt_50037_20260314_20280529_v05.bsp',
 
                           )
 
      \begintext
 
 
Solution Source Code
 
   A sample solution to the problem follows:
 
      %
      % Remote sensing lesson:  State vector lookup
      %
      function getsta()
 
      %
      % Local parameters
      %
      METAKR = 'getsta.tm';
 
      %
      % Load the kernels that this program requires.  We
      % will need a leapseconds kernel to convert input
      % UTC time strings into ET.  We also will need
      % SPK files with coverage for the bodies
      % in which we are interested.
      %
      cspice_furnsh ( METAKR );
 
      %
      % Prompt the user for the input time string.
      %
      utctim = input ( 'Input UTC Time: ', 's' );
 
      fprintf ( 'Converting UTC Time: %s\n', utctim )
 
      %
      % Convert utctim to ET.
      %
      et = cspice_str2et ( utctim );
 
      fprintf ( '   ET seconds past J2000: %16.3f\n', et )
 
      %
      % Compute the apparent state of Mercury as seen from
      % BepiColombo MPO in the J2000 frame.  All of the ephemeris
      % readers return states in units of kilometers and
      % kilometers per second.
      %
      [state, ltime] = cspice_spkezr ( 'MERCURY',  et,    ...
                                       'J2000',   'LT+S', 'MPO' );
 
      fprintf ( [ '   Apparent state of Mercury as seen ', ...
                  'from BepiColombo MPO in the\n' ,        ...
                  '      J2000 frame (km, km/s):\n']            )
 
      fprintf ( '      X = %16.3f\n', state(1) )
      fprintf ( '      Y = %16.3f\n', state(2) )
      fprintf ( '      Z = %16.3f\n', state(3) )
      fprintf ( '     VX = %16.3f\n', state(4) )
      fprintf ( '     VY = %16.3f\n', state(5) )
      fprintf ( '     VZ = %16.3f\n', state(6) )
 
 
      %
      % Compute the apparent position of Earth as seen from
      % BepiColombo MPO in the J2000 frame.  Note: We could have
      % continued using cspice_spkezr and simply ignored the
      % velocity components.
      %
      [pos, ltime] = cspice_spkpos ( 'EARTH', et,     ...
                                     'J2000', 'LT+S', 'MPO' );
 
      fprintf ( [ '   Apparent position of Earth as seen ', ...
                  'from BepiColombo MPO in the\n',          ...
                  '      J2000 frame (km):\n' ]               )
 
      fprintf ( '      X = %16.3f\n', pos(1) )
      fprintf ( '      Y = %16.3f\n', pos(2) )
      fprintf ( '      Z = %16.3f\n', pos(3) )
 
      %
      % Display the light time from target to observer.
      %
      fprintf ( [ '   One way light time between BepiColombo ', ...
                  'MPO and the apparent\n',                     ...
                  '      position of Earth (seconds): '         ...
                  '%16.3f\n' ], ltime                            )
 
      %
      % Compute the apparent position of the Sun as seen
      % from Mercury in the J2000 frame.
      %
      [pos, ltime] = cspice_spkpos ( 'SUN',   et,     ...
                                     'J2000', 'LT+S', 'MERCURY' );
 
      fprintf ( [ '   Apparent position of Sun as seen ', ...
                  'from Mercury in the \n',               ...
                  '      J2000 frame (km):\n' ]              )
 
      fprintf ( '      X = %16.3f\n', pos(1) )
      fprintf ( '      Y = %16.3f\n', pos(2) )
      fprintf ( '      Z = %16.3f\n', pos(3) )
 
      %
      % Now we need to compute the actual distance between
      % the Sun and Mercury.  The above SPKPOS call gives us
      % the apparent distance, so we need to adjust our
      % aberration correction appropriately.
      %
      [pos, ltime] = cspice_spkpos ( 'SUN',   et,     ...
                                     'J2000', 'NONE', 'MERCURY' );
 
      %
      % Compute the distance between the body centers in
      % kilometers.
      %
      dist = norm ( pos );
 
      %
      % Convert this value to AU using cspice_convrt.
      %
      dist_au = cspice_convrt ( dist, 'KM', 'AU' );
 
      fprintf ( [ '   Actual distance between Sun and Mercury ' ...
                  'body centers:\n' ]                         )
      fprintf ( '      (AU): %16.3f\n', dist_au               )
 
      %
      % Unload all kernels.
      %
      cspice_kclear;
 
      %
      % End of function getsta
      %
 
 
Solution Sample Output
 
   Execute the program:
 
      Input UTC Time: 2027 JAN 05 02:04:36
      Converting UTC Time: 2027 JAN 05 02:04:36
         ET seconds past J2000:    852386745.184
         Apparent state of Mercury as seen from BepiColombo MPO in the
            J2000 frame (km, km/s):
            X =         -683.207
            Y =        -1438.946
            Z =        -2427.819
           VX =            0.036
           VY =            2.360
           VZ =           -1.783
         Apparent position of Earth as seen from BepiColombo MPO in the
            J2000 frame (km):
            X =    -59257854.691
            Y =    185201786.218
            Z =     88178321.179
         One way light time between BepiColombo MPO and the apparent
            position of Earth (seconds):          712.193
         Apparent position of Sun as seen from Mercury in the
            J2000 frame (km):
            X =    -23429947.239
            Y =     54297427.572
            Z =     31434173.468
         Actual distance between Sun and Mercury body centers:
            (AU):            0.448
 
 
Extra Credit
--------------------------------------------------------
 
   In this ``extra credit'' section you will be presented with more complex
   tasks, aimed at improving your understanding of state computations,
   particularly the application of the different light time and stellar
   aberration corrections available in the cspice_spkezr function, and some
   common errors that may happen when computing these states.
 
   These ``extra credit'' tasks are provided as task statements, and unlike
   the regular tasks, no approach or solution source code is provided. In
   the next section, you will find the numeric solutions (when applicable)
   and answers to the questions asked in these tasks.
 
 
Task statements and questions
 
       1.   Remove the planetary ephemerides SPK from the original
            meta-kernel and run your program again, using the same inputs
            as before. Has anything changed? Why?
 
       2.   Extend your program to compute the geometric position of
            Jupiter as seen from Mercury in the J2000 frame (J2000), in
            kilometers.
 
       3.   Extend, or modify, your program to compute the position of the
            Sun as seen from Mercury in the J2000 frame (J2000), in
            kilometers, using the following light time and aberration
            corrections: NONE, LT and LT+S. Explain the differences.
 
       4.   Examine the BepiColombo MPO frames definition kernel to find
            the SPICE ID/name definitions.
 
 
Solutions and answers
 
       1.   When running the original program without the planetary
            ephemerides SPK, an error is produced by cspice_spkezr:
 
      Error using mice
      SPICE(SPKINSUFFDATA): [spkezr_c->SPKEZR->SPKEZ->SPKACS->SPKGEO]
      Insufficient ephemeris data has been loaded to compute the state of
      -121 (BEPICOLOMBO MPO) relative to 0 (SOLAR SYSTEM BARYCENTER) at
      the ephemeris epoch 2027 JAN 05 02:05:45.184. (CSPICE_N0067)
 
      Error in cspice_spkezr (line 660)
            [starg_s] = mice('spkezr_s',targ,et,ref,abcorr,obs);
 
      Error in getsta (line 42)
      [state, ltime] = cspice_spkezr ( 'MERCURY',  et,    ...
 
 
            This error is generated when trying to compute the apparent
            state of Mercury as seen from BepiColombo MPO in the J2000
            frame because despite the BepiColombo MPO ephemeris data being
            relative to Mercury, the state of the spacecraft with respect
            to the solar system barycenter is required to compute the light
            time and stellar aberrations. The loaded SPK data are enough to
            compute geometric states of BepiColombo MPO with respect to
            Mercury center, and geometric states of Mercury barycenter with
            respect to the Solar System Barycenter, but insufficient to
            compute the state of the spacecraft relative to the Solar
            System Barycenter because the SPK data needed to compute
            geometric states of Mercury center relative to its barycenter
            are no longer loaded. Run ``brief'' on the SPKs used in the
            original task to find out which ephemeris objects are available
            from those kernels. If you want to find out what is the 'center
            of motion' for the ephemeris object(s) included in an SPK, use
            the -c option when running ``brief'':
 
 
      BRIEF -- Version 4.1.0, September 17, 2021 -- Toolkit Version N0067
 
 
      Summary for: kernels/spk/de432s.bsp
 
      Bodies: MERCURY BARYCENTER (1) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              VENUS BARYCENTER (2) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              EARTH BARYCENTER (3) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              MARS BARYCENTER (4) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              JUPITER BARYCENTER (5) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              SATURN BARYCENTER (6) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              URANUS BARYCENTER (7) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              NEPTUNE BARYCENTER (8) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              PLUTO BARYCENTER (9) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              SUN (10) w.r.t. SOLAR SYSTEM BARYCENTER (0)
              MERCURY (199) w.r.t. MERCURY BARYCENTER (1)
              VENUS (299) w.r.t. VENUS BARYCENTER (2)
              MOON (301) w.r.t. EARTH BARYCENTER (3)
              EARTH (399) w.r.t. EARTH BARYCENTER (3)
              Start of Interval (UTC)             End of Interval (UTC)
              -----------------------------       -------------------------
      ----
              2027-JAN-02 23:01:53.350            2027-JAN-08 00:59:37.932
 
 
      Summary for: kernels/spk/bc_mpo_mlt_50037_20260314_20280529_v05.bsp
 
      Body: BEPICOLOMBO MPO (-121) w.r.t. MERCURY (199)
            Start of Interval (UTC)             End of Interval (UTC)
            -----------------------------       ---------------------------
      --
            2027-JAN-02 23:01:53.350            2027-JAN-08 00:59:37.932
 
      Bodies: -121000 w.r.t. BEPICOLOMBO MPO (-121)
              -121540 w.r.t. BEPICOLOMBO MPO (-121)
              -121600 w.r.t. BEPICOLOMBO MPO (-121)
              Start of Interval (UTC)             End of Interval (UTC)
              -----------------------------       -------------------------
      ----
              2027-JAN-02 23:01:53.350            2027-JAN-08 00:59:37.932
 
 
 
       2.   If you run your extended program with the original meta-kernel,
            the SPICE(SPKINSUFFDATA) error should be produced by the
            cspice_spkpos function because you have not loaded enough
            ephemeris data to compute the position of Jupiter with respect
            to Mercury. The loaded SPKs contain data for Mercury relative
            to the Solar System Barycenter, and for the Jupiter System
            Barycenter relative to the Solar System Barycenter, but the
            data for Jupiter relative to the Jupiter System Barycenter are
            missing:
 
 
         Additional kernels required for this task:
 
            1. Generic Jovian Satellite Ephemeris SPK:
 
                  jup365_2027.bsp
 
         available in the NAIF server at:
 
      https://naif.jpl.nasa.gov/pub/naif/generic_kernels/spk/
      satellites/a_old_versions
 
 
            Download the relevant SPK, add it to the meta-kernel and run
            again your extended program. The solution for the input UTC
            time "2027 JAN 05 02:04:36" when using the downloaded Jovian
            Satellite Ephemeris SPK:
 
         Actual position of Jupiter as seen from Mercury in the
            J2000 frame (km):
            X =   -623644094.418
            Y =    532767093.112
            Z =    251130102.035
 
       3.   When using 'NONE' aberration corrections, cspice_spkpos returns
            the geometric position of the target body relative to the
            observer. If 'LT' is used, the returned vector corresponds to
            the position of the target at the moment it emitted photons
            arriving at the observer at `et'. If 'LT+S' is used instead,
            the returned vector takes into account the observer's velocity
            relative to the solar system barycenter. The solution for the
            input UTC time "2027 JAN 05 02:04:36" is:
 
         Actual (geometric) position of Sun as seen from Mercury in the
            J2000 frame (km):
            X =    -23438490.402
            Y =     54294213.485
            Z =     31433347.025
         Light-time corrected position of Sun as seen from Mercury in the
            J2000 frame (km):
            X =    -23438492.550
            Y =     54294212.272
            Z =     31433346.550
         Apparent position of Sun as seen from Mercury in the
            J2000 frame (km):
            X =    -23430052.903
            Y =     54297381.156
            Z =     31434164.775
 
 
Spacecraft Orientation and Reference Frames (xform)
===========================================================================
 
 
Task Statement
--------------------------------------------------------
 
   Write a program that prompts the user for an input time string, and
   computes and displays the following at the epoch of interest:
 
       1.   The apparent state of Mercury as seen from BepiColombo MPO in
            the IAU_MERCURY body-fixed frame. This vector itself is not of
            any particular interest, but it is a useful intermediate
            quantity in some geometry calculations.
 
       2.   The angular separation between the apparent position of Mercury
            as seen from BepiColombo MPO and the nominal instrument view
            direction.
 
            The nominal instrument view direction is not provided by any
            kernel variable, but it is indicated in the BepiColombo MPO
            frame kernel cited above in the section ``Kernels Used'' to be
            the +Z axis of the MPO_SPACECRAFT frame.
 
   Use the program to compute these quantities at the epoch "2027 JAN 05
   02:04:36" UTC.
 
 
Learning Goals
--------------------------------------------------------
 
   Familiarity with the different types of kernels involved in chaining
   reference frames together, both inertial and non-inertial. Discover some
   of the vector math functions. Understand the difference between
   cspice_pxform and cspice_sxform.
 
 
Approach
--------------------------------------------------------
 
   The solution to the problem can be broken down into a series of simple
   steps:
 
       --   Decide which SPICE kernels are necessary. Prepare a meta-kernel
            listing the kernels and load it into the program.
 
       --   Prompt the user for an input time string.
 
       --   Convert the input time string into ephemeris time expressed as
            seconds past J2000 TDB.
 
       --   Compute the state of Mercury relative to BepiColombo MPO in the
            J2000 reference frame, corrected for aberrations.
 
       --   Compute the state transformation matrix from J2000 to
            IAU_MERCURY at the epoch, adjusted for light time.
 
       --   Multiply the state of Mercury relative to BepiColombo MPO in
            the J2000 reference frame by the state transformation matrix
            computed in the previous step.
 
       --   Compute the position of Mercury relative to BepiColombo MPO in
            the J2000 reference frame, corrected for aberrations.
 
       --   Determine what the nominal instrument view direction of the
            BepiColombo MPO spacecraft is by examining the frame kernel's
            content.
 
       --   Compute the rotation matrix from the BepiColombo MPO spacecraft
            frame to J2000.
 
       --   Multiply the nominal instrument view direction expressed in the
            BepiColombo MPO spacecraft frame by the rotation matrix from
            the previous step.
 
       --   Compute the separation between the result of the previous step
            and the apparent position of Mercury relative to BepiColombo
            MPO in the J2000 frame.
 
   HINT: Several of the steps above may be compressed into a single step
   using Mice functions with which you are already familiar. The ``long
   way'' presented above is intended to facilitate the introduction of the
   functions cspice_pxform and cspice_sxform.
 
   You may find it useful to consult the permuted index, the headers of
   various source modules, and the following toolkit documentation:
 
       1.   Frames Required Reading (frames.req)
 
       2.   PCK Required Reading (pck.req)
 
       3.   SPK Required Reading (spk.req)
 
       4.   CK Required Reading (ck.req)
 
   This particular example makes use of many of the different types of
   SPICE kernels. You should spend a few moments thinking about which
   kernels you will need and what data they provide.
 
 
Solution
--------------------------------------------------------
 
 
Solution Meta-Kernel
 
   The meta-kernel we created for the solution to this exercise is named
   'xform.tm'. Its contents follow:
 
      KPL/MK
 
         This is the meta-kernel used in the solution of the ``Spacecraft
         Orientation and Reference Frames'' task in the Remote Sensing
         Hands On Lesson.
 
         The names and contents of the kernels referenced by this
         meta-kernel are as follows:
 
            1. Generic LSK:
 
                  naif0012.tls
 
            2. BepiColombo MPO SCLK:
 
                  bc_mpo_step_20230117.tsc
 
            3. Solar System Ephemeris SPK, subsetted to cover only
               the time range of interest:
 
                  de432s.bsp
 
            4. BepiColombo MPO Spacecraft Trajectory SPK, subsetted
               to cover only the time range of interest:
 
                  bc_mpo_mlt_50037_20260314_20280529_v05.bsp
 
            5. BepiColombo MPO FK:
 
                  bc_mpo_v32.tf
 
            6. BepiColombo MPO Spacecraft CK, subsetted to cover only
               the time range of interest:
 
                  bc_mpo_sc_slt_50028_20260314_20280529_f20181127_v03.bc
 
            7. Generic PCK:
 
                  pck00011.tpc
 
 
      \begindata
 
       KERNELS_TO_LOAD = (
 
       'kernels/lsk/naif0012.tls',
       'kernels/sclk/bc_mpo_step_20230117.tsc',
       'kernels/spk/de432s.bsp',
       'kernels/spk/bc_mpo_mlt_50037_20260314_20280529_v05.bsp',
       'kernels/fk/bc_mpo_v32.tf',
       'kernels/ck/bc_mpo_sc_slt_50028_20260314_20280529_f20181127_v03.bc',
       'kernels/pck/pck00011.tpc'
 
                          )
 
      \begintext
 
 
Solution Source Code
 
   A sample solution to the problem follows:
 
      %
      % Remote sensing lesson:  Spacecraft Orientation and Reference Frames
      %
      function xform()
 
      %
      % Local Parameters
      %
      METAKR = 'xform.tm';
 
      %
      % Load the kernels that this program requires.  We
      % will need:
      %
      %      A leapseconds kernel
      %      A spacecraft clock kernel for BepiColombo MPO
      %      The necessary ephemerides
      %      A planetary constants file (PCK)
      %      A spacecraft orientation kernel for BepiColombo MPO (CK)
      %      A frame kernel (TF)
      %
      cspice_furnsh ( METAKR );
 
      %
      % Prompt the user for the input time string.
      %
      utctim = input ( 'Input UTC Time: ', 's' );
 
      fprintf ( 'Converting UTC Time: %s\n', utctim )
 
      %
      % Convert utctim to ET.
      %
      et = cspice_str2et ( utctim );
 
      fprintf ( '   ET seconds past J2000: %16.3f\n', et )
 
      %
      % Compute the apparent state of Mercury as seen from
      % BepiColombo MPO in the J2000 frame.  All of the ephemeris
      % readers return states in units of kilometers and
      % kilometers per second.
      %
      [state, ltime] = cspice_spkezr ( 'MERCURY', et,     ...
                                       'J2000',   'LT+S', 'MPO' );
 
      %
      % Now obtain the transformation from the inertial
      % J2000 frame to the non-inertial body-fixed IAU_MERCURY
      % frame. Since we want the apparent state in the
      % (body-fixed) IAU_MERCURY reference frame, we
      % need to correct the orientation of this frame for
      % one-way light time; hence we subtract ltime from et
      % in the call below.
      %
      sxfmat = cspice_sxform ( 'J2000', 'IAU_MERCURY', et-ltime );
 
      %
      % Now rotate the apparent J2000 state into IAU_MERCURY
      % with the following matrix multiplication:
      %
      bfixst = sxfmat * state;
 
      %
      % Display the results.
      %
      fprintf ( [ '   Apparent state of Mercury as seen ',     ...
                  'from BepiColombo MPO in the\n',             ...
                  '      IAU_MERCURY body-fixed frame (km, km/s):\n' ] )
 
      fprintf ( '      X = %19.6f\n', bfixst(1) )
      fprintf ( '      Y = %19.6f\n', bfixst(2) )
      fprintf ( '      Z = %19.6f\n', bfixst(3) )
      fprintf ( '     VX = %19.6f\n', bfixst(4) )
      fprintf ( '     VY = %19.6f\n', bfixst(5) )
      fprintf ( '     VZ = %19.6f\n', bfixst(6) )
 
      %
      % It is worth pointing out, all of the above could
      % have been done with a single use of cspice_spkezr:
      %
      %
      [state, ltime] = cspice_spkezr ( 'MERCURY',     et,      ...
                                       'IAU_MERCURY', 'LT+S',  ...
                                       'MPO'                  );
      %
      % Display the results.
      %
      fprintf ( [ '   Apparent state of Mercury as seen ',     ...
                  'from BepiColombo MPO in the\n',             ...
                  '      IAU_MERCURY body-fixed frame ',       ...
                  '(km, km/s) obtained using\n',               ...
                  '      cspice_spkezr directly:\n'           ]   )
 
      fprintf ( '      X = %19.6f\n', state(1) )
      fprintf ( '      Y = %19.6f\n', state(2) )
      fprintf ( '      Z = %19.6f\n', state(3) )
      fprintf ( '     VX = %19.6f\n', state(4) )
      fprintf ( '     VY = %19.6f\n', state(5) )
      fprintf ( '     VZ = %19.6f\n', state(6) )
 
      %
      % Note that the velocity found by using cspice_spkezr
      % to compute the state in the IAU_MERCURY frame differs
      % at the few mm/second level from that found previously
      % by calling cspice_spkezr and then cspice_sxform.
      % Computing velocity via a single call to cspice_spkezr
      % as we've done immediately above is slightly more
      % accurate than the previous method because the latter
      % accounts for the effect of the rate of change of light
      % time on the apparent angular velocity of the target's
      % body-fixed reference frame.
      %
      % Now we are to compute the angular separation between
      % the apparent position of Mercury as seen from the orbiter
      % and the nominal instrument view direction.  First,
      % compute the apparent position of Mercury as seen from
      % BepiColombo MPO in the J2000 frame.
      %
      [pos, ltime] = cspice_spkpos ( 'MERCURY',  et,     ...
                                     'J2000',    'LT+S', 'MPO' );
 
      %
      % Now compute the location of the nominal instrument view
      % direction.  From reading the frame kernel we know that
      % the instrument view direction is nominally the +Z axis
      % of the MPO_SPACECRAFT frame defined there.
      %
      bsight = [ 0.D0; 0.D0; 1.D0 ];
 
      %
      % Now compute the rotation matrix from MPO_SPACECRAFT into
      % J2000.
      %
      pform = cspice_pxform ( 'MPO_SPACECRAFT', 'J2000', et );
 
      %
      % And multiply the result to obtain the nominal instrument
      % view direction in the J2000 reference frame.
      %
      bsight = pform * bsight;
 
      %
      % Lastly compute the angular separation.
      %
      sep = cspice_convrt ( cspice_vsep(bsight, pos), ...
                            'RADIANS', 'DEGREES'         );
 
      fprintf ( [ '   Angular separation between the ',           ...
                  'apparent position of Mercury and\n',           ...
                  '      the BepiColombo MPO nominal instrument ' ...
                  'view direction\n'                              ...
                  '     (degrees):\n'                             ...
                  '      %16.3f\n' ],                             ...
                  sep                                           )
 
      %
      % Or alternatively we can work in the spacecraft
      % frame directly.
      %
      [pos, ltime] = cspice_spkpos ( 'MERCURY', et, 'MPO_SPACECRAFT', ...
                                     'LT+S', 'MPO'                  );
 
      %
      % The nominal instrument view direction is the +Z-axis
      % in the MPO_SPACECRAFT frame.
      %
      bsight = [ 0.D0; 0.D0; 1.D0 ];
 
      %
      % Lastly compute the angular separation.
      %
      sep = cspice_convrt ( cspice_vsep(bsight, pos), ...
                            'RADIANS', 'DEGREES'         );
 
      fprintf ( [ '   Angular separation between the ',           ...
                  'apparent position of Mercury and\n'            ...
                  '      the BepiColombo MPO nominal instrument ' ...
                  'view direction computed\n'                     ...
                  '      using vectors in the '                   ...
                  'MPO_SPACECRAFT frame (degrees):\n'             ...
                  '      %16.3f\n' ],                             ...
                sep                                             )
 
      %
      % Unload all kernels.
      %
      cspice_kclear;
 
      %
      % End of function xform
      %
 
 
Solution Sample Output
 
   Execute the program:
 
      Input UTC Time: 2027 JAN 05 02:04:36
      Converting UTC Time: 2027 JAN 05 02:04:36
         ET seconds past J2000:    852386745.184
         Apparent state of Mercury as seen from BepiColombo MPO in the
            IAU_MERCURY body-fixed frame (km, km/s):
            X =        -2354.697620
            Y =         -762.547549
            Z =        -1518.408470
           VX =            1.208589
           VY =            0.394259
           VZ =           -2.671125
         Apparent state of Mercury as seen from BepiColombo MPO in the
            IAU_MERCURY body-fixed frame (km, km/s) obtained using
            cspice_spkezr directly:
            X =        -2354.697620
            Y =         -762.547549
            Z =        -1518.408470
           VX =            1.208589
           VY =            0.394259
           VZ =           -2.671125
         Angular separation between the apparent position of Mercury and
            the BepiColombo MPO nominal instrument view direction
           (degrees):
                       0.009
         Angular separation between the apparent position of Mercury and
            the BepiColombo MPO nominal instrument view direction computed
            using vectors in the MPO_SPACECRAFT frame (degrees):
                       0.009
 
 
Extra Credit
--------------------------------------------------------
 
   In this ``extra credit'' section you will be presented with more complex
   tasks, aimed at improving your understanding of frame transformations,
   and some common errors that may happen when computing them.
 
   These ``extra credit'' tasks are provided as task statements, and unlike
   the regular tasks, no approach or solution source code is provided. In
   the next section, you will find the numeric solutions (when applicable)
   and answers to the questions asked in these tasks.
 
 
Task statements and questions
 
       1.   Run the original program using the input UTC time "2027 JAN 06
            15:32:05". Explain what happens.
 
       2.   Compute the angular separation between the apparent position of
            the Sun as seen from BepiColombo MPO and the nominal instrument
            view direction. Is the science deck illuminated?
 
 
Solutions and answers
 
       1.   When running the original software using as input the UTC time
            string "2027 JAN 06 15:32:05":
 
      Error using mice
      SPICE(NOFRAMECONNECT): [pxform_c->PXFORM->REFCHG] At epoch
      8.5252159418408E+08 TDB (2027 JAN 06 15:33:14.184 TDB), there is
      insufficient information available to transform from reference frame
      -121000 (MPO_SPACECRAFT) to reference frame 1 (J2000).
      MPO_SPACECRAFT is a CK frame; a CK file containing data for
      instrument or structure -121000 at the epoch shown above, as well as
      a corresponding SCLK kernel, must be loaded in order to use this
      frame. Failure to find required CK data could be due to one or more
      CK files not having been loaded, or to the epoch shown above lying
      within a coverage gap or beyond the coverage bounds of the loaded CK
      files. It is also possible that no loaded CK file has required
      angular velocity data for the input epoch, even if a loaded CK does
      have attitude data for that epoch. You can use CKBRIEF with the
      -dump option to display coverage intervals of a CK file.
      (CSPICE_N0067)
 
      Error in cspice_pxform (line 357)
            [rotate] = mice('pxform_c',from,to,et);
 
      Error in xform (line 137)
      pform = cspice_pxform ( 'MPO_SPACECRAFT', 'J2000', et );
 
 
            cspice_pxform returns the SPICE(NOFRAMECONNECT) error, which
            indicates that there are not sufficient data to perform the
            transformation from the MPO_SPACECRAFT frame to J2000 at the
            requested epoch. If you summarize the BepiColombo MPO
            spacecraft CK using the ``ckbrief'' utility program with the
            -dump option (display interpolation intervals boundaries) you
            will find that the CK contains gaps within its segment:
 
 
      CKBRIEF -- Version 6.1.0, June 27, 2014 -- Toolkit Version N0067
 
 
      Summary for: kernels/ck/bc_mpo_sc_slt_50028_20260314_20280529_f201811
      27_v03.bc
 
      Segment No.: 1
 
      Object:  -121000
        Interval Begin UTC       Interval End UTC         AV
        ------------------------ ------------------------ ---
        2027-JAN-02 23:01:53.350 2027-JAN-06 11:04:56.368 Y
        2027-JAN-06 11:08:00.779 2027-JAN-06 15:30:56.685 Y
        2027-JAN-06 15:33:04.016 2027-JAN-06 22:05:57.865 Y
        2027-JAN-06 22:10:03.746 2027-JAN-08 00:59:37.932 Y
 
 
 
            whereas if you had used ckbrief without -dump you would have
            gotten the following information (only CK segment begin/end
            times):
 
 
      CKBRIEF -- Version 6.1.0, June 27, 2014 -- Toolkit Version N0067
 
 
      Summary for: kernels/ck/bc_mpo_sc_slt_50028_20260314_20280529_f201811
      27_v03.bc
 
      Object:  -121000
        Interval Begin UTC       Interval End UTC         AV
        ------------------------ ------------------------ ---
        2027-JAN-02 23:01:53.350 2027-JAN-08 00:59:37.932 Y
 
 
 
            which has insufficient detail to reveal the problem.
 
       2.   By computing the apparent position of the Sun as seen from
            BepiColombo MPO in the MPO_SPACECRAFT frame, and the angular
            separation between this vector and the nominal instrument view
            direction (+Z-axis of the MPO_SPACECRAFT frame), you will find
            whether the science deck is illuminated. The solution for the
            input UTC time "2027 JAN 05 02:04:36" is:
 
      Angular separation between the apparent position of the Sun and the
      BepiColombo MPO nominal instrument view direction (degrees):
          135.393
 
      Science Deck illumination:
         BepiColombo MPO Science Deck IS NOT illuminated.
 
            since the angular separation is greater than 90 degrees.
 
 
Computing Sub-s/c and Sub-solar Points on an Ellipsoid and a DSK (subpts)
===========================================================================
 
 
Task Statement
--------------------------------------------------------
 
   Write a program that prompts the user for an input UTC time string and
   computes the following quantities at that epoch:
 
       1.   The apparent sub-observer point of BepiColombo MPO on Mercury,
            in the body fixed frame IAU_MERCURY, in kilometers, and the
            spacecraft altitude as the distance between the spacecraft and
            this point, in kilometers.
 
       2.   The apparent sub-solar point on Mercury, as seen from
            BepiColombo MPO in the body fixed frame IAU_MERCURY, in
            kilometers.
 
   The program computes each point twice: once using an ellipsoidal shape
   model and the
 
           near point/ellipsoid
 
   definition, and once using a DSK shape model and the
 
           nadir/dsk/unprioritized
 
   definition.
 
   The program displays the results. Use the program to compute these
   quantities at "2027 JAN 05 02:04:36" UTC.
 
 
Learning Goals
--------------------------------------------------------
 
   Discover higher level geometry calculation functions in Mice and their
   usage as it relates to BepiColombo MPO.
 
 
Approach
--------------------------------------------------------
 
   This particular problem is more of an exercise in searching the permuted
   index to find the appropriate functions and then reading their headers
   to understand how to call them.
 
   One point worth considering: how would the results change if the
   sub-solar and sub-observer points were computed using the
 
           intercept/ellipsoid
 
   and
 
           intercept/dsk/unprioritized
 
   definitions? Which definition is appropriate?
 
 
Solution
--------------------------------------------------------
 
 
Solution Meta-Kernel
 
   The meta-kernel we created for the solution to this exercise is named
   'subpts.tm'. Its contents follow:
 
      KPL/MK
 
         This is the meta-kernel used in the solution of the
         ``Computing Sub-s/c and Sub-solar Points on an Ellipsoid
         and a DSK'' task in the Remote Sensing Hands On Lesson.
 
         The names and contents of the kernels referenced by this
         meta-kernel are as follows:
 
            1. Generic LSK:
 
                  naif0012.tls
 
            2. Solar System Ephemeris SPK, subsetted to cover only
               the time range of interest:
 
                  de432s.bsp
 
            3. BepiColombo MPO Spacecraft Trajectory SPK, subsetted
               to cover only the time range of interest:
 
                  bc_mpo_mlt_50037_20260314_20280529_v05.bsp
 
            4. Generic PCK:
 
                  pck00011.tpc
 
            5. Low-resolution Mercury DSK:
 
                  mercury_lowres.bds
 
      \begindata
 
       KERNELS_TO_LOAD = (
 
       'kernels/lsk/naif0012.tls',
       'kernels/spk/de432s.bsp',
       'kernels/spk/bc_mpo_mlt_50037_20260314_20280529_v05.bsp',
       'kernels/pck/pck00011.tpc'
       'kernels/dsk/mercury_lowres.bds'
 
                         )
 
      \begintext
 
 
Solution Source Code
 
   A sample solution to the problem follows:
 
      %
      % Remote sensing lesson:  Computing Sub-s/c and Sub-solar
      % Points on an Ellipsoid and a DSK
      %
      function subpts()
 
      %
      % Local parameters
      %
      METAKR = 'subpts.tm';
 
      %
      % Load the kernels that this program requires.  We
      % will need:
      %
      %      A leapseconds kernel
      %      The necessary ephemerides
      %      A planetary constants file (PCK)
      %      A DSK file containing Mercury shape data
      %
      cspice_furnsh ( METAKR );
 
      %
      % Prompt the user for the input time string.
      %
      utctim = input ( 'Input UTC Time: ', 's' );
 
      fprintf ( 'Converting UTC Time: %s\n', utctim )
 
      %
      % Convert utctim to ET.
      %
      et = cspice_str2et ( utctim );
 
      fprintf ( '   ET seconds past J2000: %16.3f\n', et )
 
      for mi = 1:2
 
         if mi == 1
 
            %
            % Use the "near point" sub-point definition
            % and an ellipsoidal model.
            %
            method = 'NEAR POINT/Ellipsoid';
 
         else
 
            %
            % Use the "nadir" sub-point definition
            % and a DSK model.
            %
            method = 'NADIR/DSK/Unprioritized';
 
         end
 
         fprintf ( '\n Sub-point/target shape model: %s\n\n', ...
                   method                                      )
 
         %
         % Compute the apparent sub-observer point of BepiColombo MPO
         % on Mercury.
         %
         [spoint, trgepc, srfvec ] = ...
            cspice_subpnt ( method,        'MERCURY',  et,     ...
                            'IAU_MERCURY', 'LT+S',    'MPO' );
 
         fprintf ( [ '   Apparent sub-observer point of ',     ...
                     'BepiColombo MPO on Mercury \n',          ...
                     '   in the IAU_MERCURY frame (km):\n' ]      )
 
         fprintf ( '      X = %16.3f\n', spoint(1) )
         fprintf ( '      Y = %16.3f\n', spoint(2) )
         fprintf ( '      Z = %16.3f\n', spoint(3) )
         fprintf ( '    ALT = %16.3f\n', norm(srfvec) )
 
         %
         % Compute the apparent sub-solar point on Mercury
         % as seen from BepiColombo MPO.
         %
         [spoint, trgepc, srfvec ] = ...
            cspice_subslr ( method,        'MERCURY', et,        ...
                            'IAU_MERCURY', 'LT+S',    'MPO' );
 
         fprintf ( [ '   Apparent sub-solar point ',             ...
                     'on Mercury as seen from BepiColombo\n',    ...
                     '   MPO in the IAU_MERCURY frame (km):\n' ]    )
 
         fprintf ( '      X = %16.3f\n', spoint(1) )
         fprintf ( '      Y = %16.3f\n', spoint(2) )
         fprintf ( '      Z = %16.3f\n', spoint(3) )
 
      end
 
      fprintf( '\n' )
 
      %
      % Unload all kernels.
      %
      cspice_kclear;
 
      %
      % End of function subpts
      %
 
 
Solution Sample Output
 
   Execute the program:
 
      Input UTC Time: 2027 JAN 05 02:04:36
      Converting UTC Time: 2027 JAN 05 02:04:36
         ET seconds past J2000:    852386745.184
 
       Sub-point/target shape model: NEAR POINT/Ellipsoid
 
         Apparent sub-observer point of BepiColombo MPO on Mercury
         in the IAU_MERCURY frame (km):
            X =         1978.726
            Y =          640.793
            Z =         1275.611
          ALT =          463.634
         Apparent sub-solar point on Mercury as seen from BepiColombo
         MPO in the IAU_MERCURY frame (km):
            X =         1526.831
            Y =         1903.936
            Z =           -1.436
 
       Sub-point/target shape model: NADIR/DSK/Unprioritized
 
         Apparent sub-observer point of BepiColombo MPO on Mercury
         in the IAU_MERCURY frame (km):
            X =         1979.558
            Y =          641.062
            Z =         1276.148
          ALT =          462.608
         Apparent sub-solar point on Mercury as seen from BepiColombo
         MPO in the IAU_MERCURY frame (km):
            X =         1525.673
            Y =         1902.492
            Z =           -1.434
 
 
 
Extra Credit
--------------------------------------------------------
 
   In this ``extra credit'' section you will be presented with more complex
   tasks, aimed at improving your understanding of cspice_subpnt and
   cspice_subslr functions.
 
   These ``extra credit'' tasks are provided as task statements, and unlike
   the regular tasks, no approach or solution source code is provided. In
   the next section, you will find the numeric solutions (when applicable)
   and answers to the questions asked in these tasks.
 
 
Task statements and questions
 
       1.   Recompute the apparent sub-solar point on Mercury as seen from
            BepiColombo MPO in the body fixed frame IAU_MERCURY in
            kilometers using the 'Intercept/ellipsoid' method at "2027 JAN
            05 02:04:36". Explain the differences.
 
       2.   Compute the geometric sub-spacecraft point of BepiColombo MPO
            on Europa in the body fixed frame IAU_EUROPA in kilometers
            using the 'Near point/ellipsoid' method at "2027 JAN 05
            02:04:36". This point itself is not of any particular interest,
            but it is useful as input to the next ``extra credit'' task.
 
       3.   Transform the sub-spacecraft Cartesian coordinates obtained in
            the previous task to planetocentric and planetographic
            coordinates. When computing planetographic coordinates,
            retrieve Europa' radii by calling cspice_bodvrd and use the
            first element of the returned radii values as Europa'
            equatorial radius. Explain why planetocentric and
            planetographic latitudes and longitudes are different. Explain
            why the planetographic altitude for a point on the surface of
            Europa is not zero and whether this is correct or not.
 
 
Solutions and answers
 
       1.   The differences observed are due to the computation method. The
            ``Intercept/ellipsoid'' method defines the sub-solar point as
            the target surface intercept of the line containing the Sun and
            the target's center, while the ``Near point/ellipsoid'' method
            defines the sub-solar point as the the nearest point on the
            target relative to the Sun. Since Mercury is not spherical,
            these two points are not the same:
 
         Apparent sub-solar point on Mercury as seen from BepiColombo MPO
         in the IAU_MERCURY frame using the 'Near Point: ellipsoid' method
         (km):
            X =         1526.828
            Y =         1903.939
            Z =           -1.435
 
         Apparent sub-solar point on Mercury as seen from BepiColombo MPO
         in the IAU_MERCURY frame using the 'Intercept: ellipsoid' method
         (km):
            X =         1526.828
            Y =         1903.939
            Z =           -1.438
 
       2.   Download the relevant SPK prodiving ephemeris data for Europa,
            add it to the meta-kernel and run again your extended program:
 
 
         Additional kernels required for this task:
 
            1. Generic Jovian Satellite Ephemeris SPK:
 
                  jup365_2027.bsp
 
         available in the NAIF server at:
 
      https://naif.jpl.nasa.gov/pub/naif/generic_kernels/spk/
      satellites/a_old_versions
 
 
            The geometric sub-spacecraft point of BepiColombo MPO on Europa
            in the body fixed frame IAU_EUROPA in kilometers at "2027 JAN
            05 02:04:36" UTC epoch is:
 
         Geometric sub-spacecraft point of BepiColombo MPO on Europa in
         the IAU_EUROPA frame using the 'Near Point: ellipsoid' method
         (km):
            X =         -753.484
            Y =        -1366.703
            Z =          -24.296
 
       3.   The sub-spacecraft point of BepiColombo MPO on Europa in
            planetocentric and planetographic coordinates at "2027 JAN 05
            02:04:36" UTC epoch is:
 
         Planetocentric coordinates of the BepiColombo MPO
         sub-spacecraft point on Europa (degrees, km):
         LAT =           -0.892
         LON =         -118.869
         R   =         1560.835
 
         Planetographic coordinates of the BepiColombo MPO
         sub-spacecraft point on Europa (degrees, km):
         LAT =           -0.895
         LON =          118.869
         ALT =           -1.764
 
            The planetocentric and planetographic longitudes are different
            (``graphic'' = 360 - ``centric'') because planetographic
            longitudes on Europa are measured positive west as defined by
            the Europa' rotation direction.
 
            The planetocentric and planetographic latitudes are different
            because the planetocentric latitude was computed as the angle
            between the direction from the center of the body to the point
            and the equatorial plane, while the planetographic latitude was
            computed as the angle between the surface normal at the point
            and the equatorial plane.
 
            The planetographic altitude is non zero because it was computed
            using a different and incorrect Europa surface model: a
            spheroid with equal equatorial radii. The surface point
            computed by cspice_subpnt was computed by treating Europa as a
            triaxial ellipsoid with different equatorial radii. The
            planetographic latitude is also incorrect because it is based
            on the normal to the surface of the spheroid rather than the
            ellipsoid, In general planetographic coordinates cannot be used
            for bodies with shapes modeled as triaxial ellipsoids.
 
 
Intersecting Vectors with an Ellipsoid and a DSK (fovint)
===========================================================================
 
 
Task Statement
--------------------------------------------------------
 
   Write a program that prompts the user for an input UTC time string and,
   for that time, computes the intersection of the BepiColombo MPO
   SIMBIO-SYS HRIC channel boresight and field of view (FOV) boundary
   vectors with the surface of Mercury. Compute each intercept twice: once
   with Mercury' shape modeled as an ellipsoid, and once with Mercury'
   shape modeled by DSK data. The program presents each point of
   intersection as
 
       1.   A Cartesian vector in the IAU_MERCURY frame
 
       2.   Planetocentric (latitudinal) coordinates in the IAU_MERCURY
            frame.
 
   For each of the camera FOV boundary and boresight vectors, if an
   intersection is found, the program displays the results of the above
   computations, otherwise it indicates no intersection exists.
 
   At each point of intersection compute the following:
 
       3.   Phase angle
 
       4.   Solar incidence angle
 
       5.   Emission angle
 
   These angles should be computed using both ellipsoidal and DSK shape
   models.
 
   Additionally compute the local solar time at the intercept of the
   spectrometer aperture boresight with the surface of Mercury, using both
   ellipsoidal and DSK shape models.
 
   Use this program to compute values at the UTC epoch:
 
            "2027 JAN 05 02:04:36"
 
 
Learning Goals
--------------------------------------------------------
 
   Understand how field of view parameters are retrieved from instrument
   kernels. Learn how various standard planetary constants are retrieved
   from text PCKs. Discover how to compute the intersection of field of
   view vectors with target bodies whose shapes are modeled as ellipsoids
   or provided by DSKs. Discover another high level geometry function and
   another time conversion function in Mice.
 
 
Approach
--------------------------------------------------------
 
   This problem can be broken down into several simple, small steps:
 
       --   Decide which SPICE kernels are necessary. Prepare a meta-kernel
            listing the kernels and load it into the program. Remember, you
            will need to find a kernel with information about the
            BepiColombo MPO SIMBIO-SYS spectrometer.
 
       --   Prompt the user for an input time string.
 
       --   Convert the input time string into ephemeris time expressed as
            seconds past J2000 TDB.
 
       --   Retrieve the FOV (field of view) configuration for the
            BepiColombo MPO SIMBIO-SYS HRIC channel.
 
   For each vector in the set of boundary corner vectors, and for the
   boresight vector, perform the following operations:
 
       --   Compute the intercept of the vector with Mercury modeled as an
            ellipsoid or using DSK data.
 
       --   If this intercept is found, convert the position vector of the
            intercept into planetocentric coordinates.
 
            Then compute the phase, solar incidence, and emission angles at
            the intercept. Otherwise indicate to the user no intercept was
            found for this vector.
 
       --   Compute the planetocentric longitude of the boresight
            intercept.
 
   Finally
 
       --   Compute the local solar time at the boresight intercept
            longitude on a 24-hour clock. The input time for this
            computation should be the TDB observation epoch minus one-way
            light time from the boresight intercept to the spacecraft.
 
   It may be useful to consult the BepiColombo MPO SIMBIO-SYS instrument
   kernel to determine the name of the SIMBIO-SYS HRIC channel as well as
   its configuration. This exercise may make use of some of the concepts
   and (loosely) code from the ``Spacecraft Orientation and Reference
   Frames'' task.
 
 
Solution
--------------------------------------------------------
 
 
Solution Meta-Kernel
 
   The meta-kernel we created for the solution to this exercise is named
   'fovint.tm'. Its contents follow:
 
      KPL/MK
 
         This is the meta-kernel used in the solution of the
         ``Intersecting Vectors with an Ellipsoid and a DSK'' task
         in the Remote Sensing Hands On Lesson.
 
         The names and contents of the kernels referenced by this
         meta-kernel are as follows:
 
            1. Generic LSK:
 
                  naif0012.tls
 
            2. BepiColombo MPO SCLK:
 
                  bc_mpo_step_20230117.tsc
 
            3. Solar System Ephemeris SPK, subsetted to cover only
               the time range of interest:
 
                  de432s.bsp
 
            4. BepiColombo MPO Spacecraft Trajectory SPK, subsetted
               to cover only the time range of interest:
 
                  bc_mpo_mlt_50037_20260314_20280529_v05.bsp
 
            5. BepiColombo MPO FK:
 
                  bc_mpo_v32.tf
 
            6. BepiColombo MPO Spacecraft CK, subsetted to cover only
               the time range of interest:
 
                  bc_mpo_sc_slt_50028_20260314_20280529_f20181127_v03.bc
 
            7. Generic PCK:
 
                  pck00011.tpc
 
            8. SIMBIO-SYS IK:
 
                  bc_mpo_simbio-sys_v08.ti
 
            9. Low-resolution Mercury DSK:
 
                  mercury_lowres.bds
 
      \begindata
 
       KERNELS_TO_LOAD = (
 
       'kernels/lsk/naif0012.tls',
       'kernels/sclk/bc_mpo_step_20230117.tsc',
       'kernels/spk/de432s.bsp',
       'kernels/spk/bc_mpo_mlt_50037_20260314_20280529_v05.bsp',
       'kernels/fk/bc_mpo_v32.tf',
       'kernels/ck/bc_mpo_sc_slt_50028_20260314_20280529_f20181127_v03.bc',
       'kernels/pck/pck00011.tpc',
       'kernels/ik/bc_mpo_simbio-sys_v08.ti'
       'kernels/dsk/mercury_lowres.bds'
 
                         )
 
      \begintext
 
 
Solution Source Code
 
   A sample solution to the problem follows:
 
      %
      % Remote sensing lesson:  Intersecting Vectors
      % with an Ellipsoid and a DSK
      %
 
      function fovint()
 
      %
      % Local Parameters
      %
      METAKR    = 'fovint.tm';
 
      %
      % BCVLEN is the maximum number of boundary corner
      % vectors we can retrieve. We've extended this array by 1
      % element to make room for the boresight vector.
      %
      BCVLEN    = 5;
 
      %
      % Use strings to represent boolean values:
      %
      boolstr = { 'false', 'true' };
 
      %
      % We use a cell array to store our vector names, which
      % have unequal lengths.
      %
      vecnam = { 'Boundary Corner 1',
                 'Boundary Corner 2',
                 'Boundary Corner 3',
                 'Boundary Corner 4',
                 'MPO SIMBIO-SYS HRIC Boresight' };
 
      %
      % Load the kernels that this program requires.  We will need:
      %
      %    A leapseconds kernel.
      %    A SCLK kernel for BepiColombo MPO.
      %    Any necessary ephemerides.
      %    The BepiColombo MPO frame kernel.
      %    An BepiColombo MPO C-kernel.
      %    A PCK file with Mercury constants.
      %    The BepiColombo MPO SIMBIO-SYS I-kernel.
      %    A DSK file containing Mercury shape data.
      %
      cspice_furnsh ( METAKR );
 
      %
      % Prompt the user for the input time string.
      %
      utctim = input ( 'Input UTC Time: ', 's' );
 
      fprintf ( 'Converting UTC Time: %s\n', utctim )
 
      %
      % Convert utctim to ET.
      %
      et = cspice_str2et ( utctim );
 
      fprintf ( '  ET seconds past J2000: %16.3f\n', et )
 
      %
      % Now we need to obtain the FOV configuration of
      % the SIMBIO-SYS HRIC channel.
      %
      [shape, insfrm, bsight, bounds] =  ...
         cspice_getfvn ( 'MPO_SIMBIO-SYS_HRIC_FPA', BCVLEN );
 
 
      %
      % Rather than treat 'bsight' as a separate vector,
      % copy it and 'bounds' to 'scan_vecs'.
      %
      scan_vecs = [ bounds, bsight ];
 
 
      %
      % Set values of "method" string that specify use of
      % ellipsoidal and DSK (topographic) shape models.
      %
      % In this case, we can use the same methods for calls to both
      % cspice_sincpt and cspice_ilumin. Note that some SPICE routines
      % require different "method" inputs from those shown here. See the
      % API documentation of each routine for details.
      %
      method = { 'Ellipsoid',
                 'DSK/Unprioritized' };
 
      %
      % The ID code for MERCURY is built in to the library.
      % However, it is good programming practice to get
      % in the habit of checking your found-flags.
      %
      [ marsid, found ] = cspice_bodn2c ( 'MERCURY' );
 
      %
      % Return if the code was not found.
      %
      if  ~found
 
         fprintf ( 'Unable to locate the ID code for Mercury.' )
         return
 
      end
 
      %
      % Now perform the same set of calculations for each
      % vector listed in the "bounds" array. Use both
      % ellipsoidal and detailed (DSK) shape models.
      %
      for vi = 1:5
 
         fprintf ( '\nVector: %s\n', vecnam{vi} )
 
         for mi = 1:2
 
            fprintf ( '\n Target shape model: %s\n\n', method{mi} )
 
            %
            % Call sincpt to determine coordinates of the
            % intersection of this vector with the surface
            % of Mercury.
            %
            [ point, trgepc, srfvec, found ] =                 ...
              cspice_sincpt ( method{mi},   'MERCURY', et,     ...
                             'IAU_MERCURY', 'LT+S',    'MPO',  ...
                              insfrm,       scan_vecs(:,vi)        );
 
            %
            % Check the found flag.  Display a message if
            % the point of intersection was not found,
            % otherwise continue with the calculations.
            %
            if  ~found
 
               fprintf ( 'No intersection point found at this epoch.' )
 
            else
 
              %
              % Now, we have discovered a point of intersection.
              % Start by displaying the position vector in the
              % IAU_MERCURY frame of the intersection.
              %
              fprintf ( [ '  Position vector of surface intercept ', ...
                          'in the IAU_MERCURY\n', ...
                          '  frame (km):\n' ] )
 
              fprintf ( '     X   = %16.3f\n', point(1) )
              fprintf ( '     Y   = %16.3f\n', point(2) )
              fprintf ( '     Z   = %16.3f\n', point(3) )
 
              %
              % Display the planetocentric latitude and longitude
              % of the intercept.
              %
              [ radius, lon, lat ] = cspice_reclat ( point );
 
              fprintf ( [ '  Planetocentric coordinates of the ', ...
                          'intercept (degrees):\n' ]                  )
 
              fprintf ( '     LAT = %16.3f\n', lat * cspice_dpr )
              fprintf ( '     LON = %16.3f\n', lon * cspice_dpr )
 
              %
              % Compute the illumination angles at this point.
              %
              [trgepc, srfvec, phase, solar, emissn, visibl, lit] =  ...
                 cspice_illumf ( method{mi}, 'MERCURY',      'SUN',  ...
                                 et,         'IAU_MERCURY',  'LT+S', ...
                                 'MPO',      point                );
 
              fprintf ( [ '  Phase angle (degrees):',               ...
                          '             %14.3f\n'   ],              ...
                          phase  * cspice_dpr                     )
 
              fprintf ( [ '  Solar incidence angle (degrees):',     ...
                          '   %14.3f\n'   ],                        ...
                          solar  * cspice_dpr                     )
 
              fprintf ( [ '  Emission angle (degrees):',            ...
                          '          %14.3f\n'   ],                 ...
                          emissn * cspice_dpr                     )
 
              fprintf (   '  Observer visible:  %s\n',              ...
                          boolstr{visibl+1}                       )
 
              fprintf (   '  Sun visible:       %s\n',              ...
                          boolstr{lit+1}                          )
 
              if vi == 5
 
                 %
                 % Compute local solar time corresponding to the TDB
                 % light time corrected epoch at the boresight
                  % intercept.
                 %
                 [ hr, min, sc, time, ampm ] =                      ...
                    cspice_et2lst ( trgepc, marsid,                 ...
                                  lon,    'PLANETOCENTRIC'        );
 
                 fprintf( [ '\n  Local Solar Time at boresight',    ...
                            ' intercept (24 Hour Clock):\n',        ...
                            '     %s\n' ],                          ...
                            time                                  )
               end
               %
               % End of LST computation block.
               %
 
            end
            %
            % End of shape model loop.
            %
 
         end
         %
         % End of vector loop.
         %
 
      end
 
      fprintf ( '\n' );
 
      %
      % Unload kernels we loaded at the start of the function.
      %
      cspice_unload ( METAKR );
 
      %
      % End of function fovint
      %
 
 
Solution Sample Output
 
   Execute the program:
 
      Input UTC Time: 2027 JAN 05 02:04:36
      Converting UTC Time: 2027 JAN 05 02:04:36
        ET seconds past J2000:    852386745.184
 
      Vector: Boundary Corner 1
 
       Target shape model: Ellipsoid
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1973.717
           Y   =          645.436
           Z   =         1281.009
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.670
           LON =           18.109
        Phase angle (degrees):                     44.735
        Solar incidence angle (degrees):           44.622
        Emission angle (degrees):                   1.280
        Observer visible:  true
        Sun visible:       true
 
       Target shape model: DSK/Unprioritized
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1974.257
           Y   =          645.602
           Z   =         1281.346
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.670
           LON =           18.108
        Phase angle (degrees):                     44.735
        Solar incidence angle (degrees):           46.703
        Emission angle (degrees):                   4.145
        Observer visible:  true
        Sun visible:       true
 
      Vector: Boundary Corner 2
 
       Target shape model: Ellipsoid
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1979.643
           Y   =          647.354
           Z   =         1270.875
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.391
           LON =           18.108
        Phase angle (degrees):                     45.641
        Solar incidence angle (degrees):           44.447
        Emission angle (degrees):                   1.198
        Observer visible:  true
        Sun visible:       true
 
       Target shape model: DSK/Unprioritized
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1980.449
           Y   =          647.601
           Z   =         1271.407
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.391
           LON =           18.108
        Phase angle (degrees):                     45.641
        Solar incidence angle (degrees):           43.796
        Emission angle (degrees):                   1.894
        Observer visible:  true
        Sun visible:       true
 
      Vector: Boundary Corner 3
 
       Target shape model: Ellipsoid
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1983.307
           Y   =          636.037
           Z   =         1270.876
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.391
           LON =           17.781
        Phase angle (degrees):                     44.501
        Solar incidence angle (degrees):           44.666
        Emission angle (degrees):                   1.195
        Observer visible:  true
        Sun visible:       true
 
       Target shape model: DSK/Unprioritized
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1984.034
           Y   =          636.285
           Z   =         1271.361
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.391
           LON =           17.781
        Phase angle (degrees):                     44.501
        Solar incidence angle (degrees):           45.429
        Emission angle (degrees):                   2.027
        Observer visible:  true
        Sun visible:       true
 
      Vector: Boundary Corner 4
 
       Target shape model: Ellipsoid
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1977.381
           Y   =          634.119
           Z   =         1281.010
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.670
           LON =           17.780
        Phase angle (degrees):                     43.576
        Solar incidence angle (degrees):           44.840
        Emission angle (degrees):                   1.278
        Observer visible:  true
        Sun visible:       true
 
       Target shape model: DSK/Unprioritized
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1978.158
           Y   =          634.384
           Z   =         1281.499
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.670
           LON =           17.781
        Phase angle (degrees):                     43.576
        Solar incidence angle (degrees):           45.349
        Emission angle (degrees):                   1.920
        Observer visible:  true
        Sun visible:       true
 
      Vector: MPO SIMBIO-SYS HRIC Boresight
 
       Target shape model: Ellipsoid
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1978.524
           Y   =          640.740
           Z   =         1275.950
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.530
           LON =           17.944
        Phase angle (degrees):                     44.609
        Solar incidence angle (degrees):           44.644
        Emission angle (degrees):                   0.059
        Observer visible:  true
        Sun visible:       true
 
        Local Solar Time at boresight intercept (24 Hour Clock):
           09:46:41
 
       Target shape model: DSK/Unprioritized
 
        Position vector of surface intercept in the IAU_MERCURY
        frame (km):
           X   =         1979.357
           Y   =          641.010
           Z   =         1276.487
        Planetocentric coordinates of the intercept (degrees):
           LAT =           31.530
           LON =           17.944
        Phase angle (degrees):                     44.609
        Solar incidence angle (degrees):           45.349
        Emission angle (degrees):                   1.138
        Observer visible:  true
        Sun visible:       true
 
        Local Solar Time at boresight intercept (24 Hour Clock):
           09:46:41
 
 
 
Extra Credit
--------------------------------------------------------
 
   There are no ``extra credit'' tasks for this step of the lesson.
 
