Document title: NSSDC user's guide for data from the Ulysses SWOOPS plasma
experiment: The electron experiment 
Project: ULYSSES
NDADS Datatype: SWOOPS_ELE_HIRES 
Super-EID: DOCUMENT                      
There may be other documents also identified by this super-EID.
NDADS filename: SWOOPS_ELECTRON_USERS_GUIDE_V01.DOC       
TRF entry: b46604.txt in NSSDC's controlled digital document library, Feb. 1998.
Document text follows:
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     NSSDC USER'S GUIDE FOR DATA FROM THE ULYSSES SWOOPS PLASMA EXPERIMENT:
                        THE ELECTRON EXPERIMENT


                             TABLE OF CONTENTS

1. OVERVIEW OF THE SWOOPS EXPERIMENT
2. INTRODUCTION TO THE SWOOPS ELECTRON EXPERIMENT
3A. INSTRUMENT OPERATION-SUMMARY 
3B. INSTRUMENT OPERATION-DETAILED DESCRIPTION
4. DATA REDUCTION ALGORITHMS
5. DESCRIPTION AND FORMAT OF DATA SUBMITTED TO THE NSSDC


1. OVERVIEW OF THE SWOOPS EXPERIMENT

The SWOOPS (Solar Wind Observations Over the Poles of the Sun) experiment has
two electrostatic analyzers, one for positive ions and one for electrons. The
instrument is fully described in: The Ulysses Solar Wind Plasma Experiment, S.
J. Bame, D. J. McComas, B. L. Barraclough, J. L. Phillips, K. J. Sofaly, J. C.
Chavez, B. E. Goldstein, and R. K. Sakurai, Astronomy and Astrophysics
Supplement Series, Ulysses Instruments Special Issue, Vol. 92, No. 2, p.
237-265, 1992. The electron and ion analyzers are separate instruments that
operate asynchronously. For this reason, the data from the two sensors are
submitted separately to the NSSDC. This document describes the electron
analyzer and the data submitted to the NSSDC for that analyzer; the ion
experiment is described in a comparable document that accompanies the ion
data. 

2. INTRODUCTION TO THE SWOOPS ELECTRON EXPERIMENT

The SWOOPS electron spectrometer is a 120-degree spherical section electrostatic
analyzer which measures the 3-d velocity space distributions of solar wind
electrons.  In its normal solar wind mode, the instrumental energy range is 
1.6 to 862 eV in the spacecraft frame.  Since the spacecraft generally charges
to +2 to +15 volts, 2 to 15 eV is subtracted from the measured energies 
(electrons measured at energies below the spacecraft potential are electro-
statically trapped photoelectrons). The beginning of scientifically useful 
SWOOPS data is at the beginning of Day 322 of 1990.

The electron instrument is subject to a "sleep mode" triggered by changes in
the spacecraft configuration.  The first time this mode occurred it caused a 
long gap in the electron (but not the ion) data: from 0621 UT on day 346 of 1990
until 2052 UT on day 362. Subsequently, procedures were developed to recognize, 
correct, and prevent this sleep mode, thus minimizing its impact.  However, 
there are occasional gaps in the electron data when the SWOOPS ion sensor, 
and other Ulysses experiments, were returning data. 


3A. INSTRUMENT OPERATION-SUMMARY 

Each spectrum takes 2 minutes to accumulate, but telemetry takes longer.
When the spacecraft is being actively tracked and is returning data at its
highest bit rate, spectra are returned every 2.3 minutes (low angular resolution
mode) or every 5.7 minutes (high resolution mode).  During playback of stored
data, the spectral repetition rate is every 4.7 minutes (low angular resolution)
or every 11.3 minutes (high resolution).  These modes will be described in the
next paragraph.  For most of the mission, the instrument has been in high angular
resolution mode, resulting in spectra every 5.7 minutes when the spacecraft is
being tracked, or every 11.3 minutes for playback.  The amount of spacecraft 
tracking depends on the mission phase.


3B. INSTRUMENT OPERATION-DETAILED DESCRIPTION

The electron analyzer is provided with a 22-level high voltage supply to
cover a range of ion energies from 0.8 to 862 eV.  At any given time, either
the top 20 or bottom 20 of these voltage levels are used.  Except from a period
from instrument turn-on in November 1990 through December 3, 1990, the 
instrument has been in high-energy mode throughout the mission, resulting in 
an energy range of 1.6 to 862 eV.  Prior to that time, the instrument 
alternated between low-energy (0.8 to 454 eV) and high-energy (1.6 to 862 eV) 
spectra.

The analyzer uses 7 channel electron multipliers (CEMs) to count electrons 
discretely over 95% of the unit sphere in look direction.  For telemetry 
conservation, 2 out of every 3 spectra are "two-dimensionalized" onboard the
spacecraft, that is the count rates are averaged over all 7 CEMs.  These 2-d
spectra thus return electron counts as a function of energy and spacecraft
spin angle.  The full 3-d spectra return counts as a function of energy, 
spacecraft spin angle, and polar angle (measured from the spacecraft spin
axis, which points at Earth).

There are two angular resolution schemes which are ground commanded.  In the
high resolution scheme, which has been used for most of the mission, the 3-d
spectra incorporate 32 spin-angle steps, for a total spectral content of
20 energies x 32 azimuths x 7 polar angles.  The 2-d spectra incorporate
64 spin angle steps, for a total of 20 energies x 64 azimuths x 1 CEM-averaged
polar angle (90 degrees from the spin axis).  In the low resolution scheme, 
both 2-d and 3-d spectra incorporate only 16 spin angle steps, but provide
a higher spectral repetition rate, as described in the previous section.


4. DATA REDUCTION ALGORITHMS

The first step in data reduction is determination of the spacecraft potential.
This is done by identifying inflections in the angle-averaged energy spectra.
Potential averages +6V, with higher values for low-density plasma and lower
(but still positive) values for high-density plasma.  A second inflection is
also identified in the spectra, corresponding to the break between thermal
("core") and suprathermal ("halo") populations.  The count rate arrays
are then corrected for spacecraft potential and converted to phase-space
density arrays using the "plane-parallel correction" (e.g., Scime et al., JGR,
p. 14769, 1994), a correction which affects not only the energies but also the 
direction of motion of the measured electrons.

Plasma moments are then calculated by numerical integration of the velocity-
weighted ion distributions.  A total integration is performed from the
spacecraft potential (corresponding to zero energy solar wind electrons) to
the instrumental energy limit.  Analogous core and halo integrations are 
performed for the parts of the distribution above and below the core-halo
energy break point.  Since the first few eV above the spacecraft potential
are contaminated with photoelectrons on non-radial trajectories, it is 
necessary to use a biMaxwellian fit to the core distribution to fill in
this part of the distribution; the total and core integration results are
corrected based on this fit.

The integrations produce density, temperature components, velocity, and 
heat flux.  At this time, only densities and scalar temperatures are being 
provided for archiving.  The SWOOPS ion instrument provides much more 
accurate measurements of solar wind velocity; ion results should be used 
for velocities.

In general, the integrated density is similar, but not identical, to the
sum of the core and halo densities.  The lack of exact agreement is due
to imprecision in separating the core and halo distributions.  On rare
occasions, gross discrepancies exist between the total density and the
sum of core and halo; such data should be used with caution.

Uncertainties in the spacecraft potential determination can create errors
in the density and temperature calculations.  These problems are particularly
severe when the solar wind is rarefied and cold, making it difficult to 
separate the photoelectron and thermal distributions.   Occasionally, 
gross discrepancies appear between the SWOOPS ion and electron density 
determinations.  When such discrepancies appear, the SWOOPS electron values 
(both density and temperature) are generally incorrect.  

During some intervals, a "ripple" can be seen between the 2-d and 3-d densities
and temperatures.  This is an unavoidable effect of plasma anisotropies.  The
best procedure in this case is to compare the densities with those from the
SWOOPS ion experiment (charge density  = proton density + twice alpha density).

The URAP experiment aboard Ulysses operates a radio-frequency sounder which
can distort the low-energy electron distributions.  Spectra measured during
sounder operations are flagged in the data and should be used with caution.


5. DESCRIPTION AND FORMAT OF DATA SUBMITTED TO THE NSSDC

The data provided to the NSSDC are the total, core, and halo electron densities
and scalar temperatures at full instrumental time resolution, plus spacecraft
position.

The time specified in the file is the center of each 2-minute spectrum.  
This time roughly corresponds to the center of the core distribution; the most
appropriate time for the halo properties is roughly 30 seconds later.

The data files were created with Fortran on a Vax running VMS.  Four files 
per calendar year are provided, with a naming scheme as follows:

U92183BAMELE.DAT corresponds to data starting on day 183 of year 1992.

They can be opened and read as follows:

      open (3, file='U92183BAMELE.DAT', status='old')

c      iyr           - year
c      idoy          - day of year (Jan 1 = 001)
c      ihr           - hour, UT
c      imin          - minute, UT
c      isec          - second, UT
c      idim          - dimension of spectrum (2 or 3)
c      isound        - sounder flag: 1=sounder off; 2=sounder on
c      sunsc         - sun-spacecraft distance, AU
c      hlat          - heliospheric latitude of spacecraft, degrees
c      hlong         - heliospheric (Carrington) longitude of spacecraft, deg
c      dene          - total electron number density per cubic cm
c      denc          - core electron number density per cubic cm
c      denh          - halo electron number density per cubic cm
c      tempe         - total electron temperature, Kelvins
c      tempc	     - core electron temperature, Kelvins
c      temph         - halo electron temperature, Kelvins

      read (3, 1) iyr,idoy,ihr,imin,isec,idim,isound,sunsc,hlat,hlong,
     >            dene,denc,denh,tempe,tempc,temph
 
1     format(1x,i2,1x,i3,3(1x,i2),2(1x,i1),f7.4,2f7.2,6e13.5)

Missing or known bad density and temp data is replaced with a flag (1.e32) throughout.


7. FURTHER INFORMATION

For information on acquiring other types of data not provided to the the NSSDC,
contact the Principal Investigator, Dr. John L. Phillips, at the Los Alamos
National Laboratory, jlphillips@lanl.gov, 505-667-3101. Also contact Dr.
Phillips for information on the reduction and analysis of data from the
electron experiment. For information on the reduction and analysis of data
from the positive ion experiment, contact Dr. Bruce E. Goldstein at the Jet
Propulsion Laboratory, bgoldstein@jplsp2.jpl.nasa.gov, 818-354-7366.