This directory contains all of the metadata associated with this CD-ROM.
This information is divided into a series of separate template files. These
include the files MISSION.CAT, describing the Pioneer Venus mission,
INSTHOST.CAT, describing the Pioneer Venus Orbiter (PVO) and Multiprobe
spacecraft, *INST.CAT files, describing the PVO instruments, *DS.CAT files,
describing the various data sets contained on this volume, and the *REF.CAT
describing the references cited on this volume.

These files are primarily for use in the PDS Data Set Catalog
(http://pds.jpl.nasa.gov/catalog.html) and some of the information
contained here may be found elsewhere on the CD-ROM.

The following table describes the contents of the catalog templates
contained in this directory.

file            contents
------------------------------------------------------------------
MISSION.CAT     Mission template for the Pioneer Venus mission
INSTHOST.CAT    Instrument Host (Spacecraft) template for PVO and Probes

Electric Field Detector (OEFD) 

OEFDHIDS.CAT    OEFD High resolution data set description
OEFDLODS.CAT    OEFD Low resolution data set description
OEFDINST.CAT    OEFD Instrument description
OEFD_REF.CAT    OEFD References

Magnetometer (OMAG) 

OMAGHIDS.CAT    OMAG High resolution three sensor data set description
OMAGLODS.CAT    OMAG Low resolution three sensor data set description
OMAGINST.CAT    OMAG Instrument description
OMAG_REF.CAT    OMAG References References
OMAGPHDS.CAT    OMAG High resolution single sensor data set description
OMAGPLDS.CAT    OMAG Low resolution single sensor data set description

Ephemeris (POS)

EPHEM_DS.CAT    Ephemeris data set description.
EPHEMREF.CAT    Ephemeris data set references.

SOFTWARE.CAT    Software program description.

---------------------------------------------------------------------------
The PDS no longer catalogs coordinate system information. The following
text, found elsewhere on this disk, in a file called COORDSYS.TXT, was
extracted from the old PDS coordinate system catalog:


PVO Spinning Spacecraft coordinates (PVO_SSCC):

       Spacecraft coordinates (Xs, Ys, Zs) are used to describe the
       physical mounting locations of the Sun sensors, the star sensor,
       and the experiment sensors. The spacecraft coordinate system is
       centered at the spacecraft center of mass and rotates with the
       spacecraft. The Xs-Ys plane is parallel to the plane of the
       spacecraft equipment shelf. The positive Zs axis points out the
       top of the spacecraft. The positive Ys axis coincides with the
       split line of the equipment shelf. With no spacecraft wobble or
       nutation, the spacecraft positive Zs axis will coincide with the
       spin axis and the equipment shelf will thus be perpendicular
       to the spin axis.

PVO Inertial Spacecraft Coordinates (PVO_ISCC):

       The inertial spacecraft coordinate system for the PVO spacecraft
       is same coordinate system as the spinning spacecraft coordinate
       system (SSCC) except that it does not spin with the spacecraft.
       Thus the Spin axis or positive Z axis direction is the same in
       both systems and it points out the top (toward the BAFTA assembly)
       of the spacecraft.  The axes in the spin plane are defined as
       follows: The X-Z plane is defined to contain the spacecraft-Sun
       vector with the positive X direction being sunward,
       and the coordinate system is defined to be right-handed. The
       transformation from SSCC to ISCC is:
       _                             _
       | cos(p)    -sin(p)      0    |
       | sin(p)     cos(p)      0    |
       |  0          0          1    |
       _                             _

       where p is the spin phase angle measured in ISSC coordinates.

Venus Solar Orbital Coordinates (VSO):

      The VSO coordinate system is a Cartesian coordinate
      system centered on Venus.  The components of this 
      coordinate system are as follows:  The X axis direction points
      from the center of Venus to the Sun, taken positive towards the
      Sun, the Z axis is parallel to the northward pole of the Venus
      orbital plane, the Y axis completes the right-handed set and
      points towards dusk. Locations of bodies (spacecraft) given in
      VSO coordinates are usually represented in units of
      Venus radii where Rv = 6052 km.

Equatorial Inertial Spherical Coordinates (ISC_EQTR):

      The Equatorial Inertial Spherical Coordinate system is defined by the
      equatorial plane of the Earth for the reference epoch of 1950.0. The
      principal direction vectors of this system are the Earth's Equatorial
      Pole and the Vernal Equinox direction. The components of the coordinate
      system are:

      1) Radius: Distance from the reference body to the spacecraft.
      2) Declination: The angle between the reference body-spacecraft
         radius vector and the reference body equatorial plane, measured
         positive north of the equatorial plane.
      3) Right Ascension: The angle between the Vernal Equinox line and the
         projection of the reference body-spacecraft radius vector onto the
         Earth equatorial plane, measured eastward from the Vernal Equinox
         line.
      4) Inertial Speed (V): The magnitude of the inertial velocity of the
         spacecraft.
      5) Inertial Flight Path Angle (GAMMA): The angle between the spacecraft
         inertial velocity vector and the plane perpendicular to the
         reference-body-to-spacecraft (radius) vector; positive when measured
         away from the reference body.
      6) Inertial Azimuth Angle (SIGMA): The angle, measured in the plane
         perpendicular to the reference-body-to-spacecraft (radius) vector,
         from the projection of true north into that plane eastward to the
         projection of the inertial velocity vector into that plane.

      When the reference body is taken to be the Earth, this becomes the
      coordinate system EME-50 (FK-4).

Inertial Spherical Coordinates - Ecliptic (ISC_ECLP):

      The Ecliptic Inertial Spherical Coordinate system is defined by the
      ecliptic plane of the Earth for the reference epoch of 1950.0. The
      principal direction vectors of this system are the Earth's Ecliptic
      Pole and the Vernal Equinox direction. The components of the coordinate
      system are:

      1) Radius: Distance from the reference body to the spacecraft.
      2) Celestial Latitude: The angle between the reference body-spacecraft
         radius vector and the reference body ecliptic plane, measured positive
         north of the ecliptic plane.
      3) Celestial Longitude: The angle between the Vernal Equinox line and the
         projection of the reference body-spacecraft radius vector onto the
         Earth ecliptic plane, measured eastward from the Vernal Equinox line.
      4) Inertial Speed (V): The magnitude of the inertial velocity of the
         spacecraft.
      5) Inertial Flight Path Angle (GAMMA): The angle between the spacecraft
         inertial velocity vector and the plane perpendicular to the
         reference-body-to-spacecraft (radius) vector; positive when measured
         away from the reference body.
      6) Inertial Azimuth Angle (SIGMA): The angle, measured in the plane
         perpendicular to the reference-body-to-spacecraft (radius) vector,
         from the projection of true north into that plane eastward to the
         projection of the inertial velocity vector into that plane.

      When the reference body is taken to be the Earth, this becomes the
      coordinate system ECL-50.

Earth-Sun Line Cartesian Coordinates (ESL-CART):

      The Earth-Sun Line Cartesian coordinate system is defined to have
      the X-Y plane be the instantaneous ecliptic plane with the positive
      Z direction taken to be the Sun-centered, northward ecliptic normal.
      The positive X direction is away from the Sun along the Sun-Earth line.
      Y completes the right-handed set and is positive away from the Sun.

      Note: This system rotates with the Earth about the Sun.

Inertial Cartesian Coordinate System - Equatorial (ICC_EQTL):

     The Equatorial Inertial Cartesian Coordinate System is defined for
     the reference epoch of 1950.0 The X-direction is positive
     away from the reference body towards the Vernal Equinox which is determined
     by the line of intersection between the mean Earth equatorial plane and
     the ecliptic plane of reference. The Y direction is measured outward
     from the center of the reference body, perpendicular to and east of the
     the X-axis, and lying in the equatorial plane of reference. The Z direction
     is positive toward the north equatorial pole of reference, from the center
     of the reference body.

Inertial Cartesian Coordinate System - Ecliptic (ICC_ECLP):

     The Equatorial Inertial Cartesian Coordinate System is defined for
     the reference epoch of 1950.0 The X-direction lies in the Ecliptic Plane
     and is positive away from the reference body towards the Vernal Equinox
     which is determined by the line of intersection between the mean Earth
     equatorial plane and the ecliptic plane of reference. The Y direction 
     is measured outward from the center of the reference body, perpendicular
     to and east of the the X-axis, and lying in the ecliptic plane of
     reference. The Z direction is positive toward the north ecliptic pole of
     reference, from the center of the reference body.


Body-Fixed Spherical Coordinate System (BFS_CRDS):

     The body-fixed spherical coordinate system is the familiar Geographic
     coordinate system at Earth generalized to other planets. The system
     consists of the components Radius, Latitude, Longitude. The definition
     of the prime meridian varies for each planet as does the rotation
     period. It is crucial to know the exact definition of these variables
     when changing the reference body.

     Note: This coordinate system rotates with the reference body.

Spacecraft Centered Ecliptic Coordinates (SCC_ECLP):

     The Spacecraft Centered Ecliptic coordinates system (Xe, Ye, Ze) is
     used to describe the locations of the roll reference celestial objects
     (Sun or star) and the planet Venus. The coordinate system is centered
     at the spacecraft center of mass. The Xe-Ye plane is parallel to the
     Ecliptic Plane and the Ze axis points to the North Ecliptic Pole.
     The Xe axis points towards the Vernal Equinox. Directions in this
     coordinate system are described by Celestial Longitude and Celestial
     Latitude.

Non-Rotating Spin Coordinates (NRSC):

     The roll angle of the roll reference object will be calculated in this
     coordinate system as well as the roll angles of the Fs, RIP, RAM, and
     NADIR signals. The non-rotating coordinate system (Wx, Wy, Wz) is
     centered at the spacecraft center of mass. The Wz-axis is parallel to the
     spacecraft spin axis. The Wx-Wy plane is perpendicular to the spacecraft
     spin axis. The Wx-Wz plane includes the Vernal Equinox of reference.
     Thus the Wx-axis is at the intersection of the plane perpendicular to
     the spacecraft spin axis and the plane containing the spin axis and the
     Vernal Equinox. Roll angles in this coordinate system are measured in the
     Wx-Wy plane from the roll reference direction.