Instrument Description:

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The Pioneer Venus Orbiter Plasma Wave Investigation

F.L. Scarf, W.W.L. Taylor, and P.F. Virobik

IEEE Transaction on Geoscience and Remote Sensing,
                January 1980
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Abstract

The Pioneer Venus plasma wave instrument has a self-
contained balanced electric dipole (effective length = 0.75
m) and a 4-channel spectrum analyzer (30-percent band width
filters with center frequencies at 100 Hz, 5.4 kHz, and 30
kHz).  The channels are continuously active and the highest
Orbiter telemetry rate (2048 bps) yields 4 spectral scans/s.
The total mass of 0.55 kg includes the electronics, the
antenna, and the antenna deployment mechanism.  This report
contains a brief description of the instrument design and a
discussion of the in-flight performance.

Introduction

Since December 5, 1978, the electric field detector in the
Pioneer Venus Orbiter has been providing measurements of
wave activity in the plasma environment of Venus.  The
Orbiter plasma wave instrument uses a short self-contained
electric dipole to detect the signals which are processed in
4 continuously active bandpass channels covering the
frequency range from 100 Hz to 30 kHz.  The instrument is
gathering data on many aspects of the mode of interaction
between the solar wind and the ionosphere (e.g., on
processes that develop in the upstream solar wind region,
near the bow shock and ionopause and within the ionosphere,
ionosheath, and wake cavity).  The instrument was also
designed to collect data on whistler mode electromagnetic
noise bursts from the atmosphere, and it appears that
lightning from Venus is being detected by the Orbiter wave
instrument.

Bl preamplifier input uses a pair of 2N5556
field effect transistors specifically selected to provide
matched gains and low noise levels.  The input circuit was
designed to have low input capacitance in order to minimize
possible effects of varying antenna capacitance associated
with changing plasma sheath conditions.
 
Background

The original proposal for a plasma wave instrument on the
Pioneer Venus Orbiter was based on the design of the
electric field detectors operating on Pioneer 8, 9 [1].  In
fact, it was first proposed that an existing Pioneer 9
flight spare unit be flown, using a spacecraft element (boom
or antenna) as an unbalanced electric field dipole.  With
this plan, the requirements on the spacecraft would have
been minimal (the Pioneer 9 spare has four analog telemetry
outputs, no internal commands, a mass of 0.36 kg, and total
power consumption of 420 mW; the proposed antenna concept
would have required some mass addition for the antenna
diplexer and cabling, but no deployment mechanisms or
deployment commands were required).  this proposal was
accepted in principle, but it turned out to be impossible to
use the Pioneer 9 spare or to use a spacecraft element as an
antenna.  At this point it became necessary to design a new
Pioneer Venus plasma wave instrument with the following
constraints:  a) total mass near 0.5 kg, including antenna
and deployment mechanism.  b) power consumption near 0.5 W;
c) no commands for antenna deployment; and d) 4 analog
telemetry outputs.  Another significant constraint on the
antenna design involved the need to provide sufficient
rigidity so that the antenna would not strike the spacecraft
or the solar arrays during powered flight (such as the
Centaur burns near earth and the burn of the Orbit Insertion
Motor at Venus).

Instrument Description

The constraints discussed above presented a number of
serious mechanical and electronic problems and it was clear
that the instrument would have to have a limited number of
bandpass channels and a relatively small antenna.  The
science requirements of the Venus mission provided
additional constraints, such as the need to cover a
frequency range from below the anticipated electron
cyclotron frequency up to the nominal interplanetary
electron plasma frequency.  the high speed of the spacecraft
through the shock, ionopause, and ionosphere required the
use of continuously active channels to measure rapid
temporal variations without error.  Finally, in order to use
a body-mounted sensor on a spinning spacecraft with
irregular solar arrays, it was evident that a balanced
electric dipole would be needed to achieve common mode
rejection of interference signals.

The resulting design is shown in Fig. 1, which contains a
block diagram of the electronics circuit and a drawing of
the mounting of the deployed antenna on the Orbiter
spacecraft.  The electronics is packaged in a two-level box,
as shown in Fig. 2.  The dimensions of the upper part are
12.2 cm x 6.6 cm x 5.5 cm, and those of the base are 19 cm x
6.6 cm x 2 cm, with a total unit mass of 0.5 kg.  The key to
the overall instrument design was fundamentally related to
the plan for mounting and deploying the antenna.  As shown
in Figs. 3 and 4, the entire 50-g antenna unit was mounted
directly on the electronics box, and the individual spring-
loaded antenna elements were stowed against the inside
surface of the launch vehicle fairing, so that they deployed
automatically as the fairing was ejected.  In the deployed
position the of each wire grid is 0.69 m from the point of
connection to the electronics unit, and the sphere-to-sphere
separation is 0.76 m.  The wire grids are placed at the ends
in order to provide a lumped capacitance with small
collecting area.  The individual wire circles have diameters
of 10.5 cm, and the antenna effective length is 0.75m.

The instrument antenna are mounted near the top surface
of the spacecraft bus (note that the Pioneer Venus 
Orbiter is inverted: the top of the spacecraft and the 
spin axis point to southern Venus and Solar latitudes).
The axis of the antenna, which bisects the two elements,
is at -177.5 degrees with respect to the sun-sensor
location, where positive angles are defined in the same
direction as the spacecraft rotation.  The effective 
dipole orientation is 90 degrees to this direction.

Since this antenna system with small collecting area
responds to induced electric fields, the transfer function
for the antenna/input circuit is determined by placing the
entire unit in a large parallel-plate capacitor.  The
capacitor is driven with a calibrated signal generator, and
the preamplifier output is measured as the frequency is
varied.

The differential preamplifier input uses a pair of 2N5556
field effect transistors specifically selected to provide
matched gains and low noise levels.  The input circuit was
designed to have low input capacitance in order to minimize
possible effects of varying antenna capacitance associated
with changing plasma sheath conditions.

The four filters of the 4-channel spectrum analyzer have
frequency response curves similar to those used in the
400-Hz, 22-kHz, and 30-kHz channels on Pioneer 8, 9, [1],
but for the Pioneer Venus Orbiter we selected filters with
30-percent fractional bandwidth rather than the 15-percent
units used previously.  The automatic gain control amplifiers
used here have rise times on the order of 50 ms, with decay 
times approximately 500 ms.

Finally, the telemetry interface is straightforward.  The 4
analog outputs are converted to digital form by the
spacecraft and transmitted to earth in a way that depends on
the selected format and on the telemetry rate.  One minor
frame has 512 bits, and the spacecraft transmission rates
range from 4 minor frames/s down to 1 minor frame/64 s.
Near periapsis the customary rates have been 2 to 4 minor
frames/s during the first year in orbit.

In two of the spacecraft telemetry formats (Periapsis D-the
"Optical" format, and Periapsis B-an "Aeronomy" format) no
plasma wave measurements are made.  In format E ("Radar
Mapping" format) only the 100-Hz channel is sampled.  For
the other 6 telemetry formats an entire 4-channel spectral
scan is obtained with every minor frame readout.  this has
generally provided 2-4 scans/s near periapsis.

In-Flight Performance

The wave instrument has been acquiring data almost
continuously since launch on May 20, 1978, and we find that
the in-flight operation is remarkably free of interference
associated with pickup of noise from spacecraft or
experiment subsystems.  The only known instrumental effect
involves the detection of regular low level amplitude
ripples when the spacecraft is in sunlight.  This is
illustrated in Fig. 5, which shows wave measurements from
the region of an outbound bow shock crossing (top four
panels), along with a profile of the B-field magnitude
(bottom panel; data supplied by C.T. Russell).  The
amplitude modulation is evident only when the natural plasma
wave activity is low, and this effect is a measure of the
sun-oriented anisotropy of the plasma sheath surrounding the
spacecraft, which is not an equipotential.  The observed
ripple arises because the antenna on the spinning spacecraft
is at a different angular position with respect to the sun
during each successive sampling.

When the spacecraft is in darkness the ripple is absent, but
as expected, the achievable sensitivity is not really
improved.  fig. 6 shows some high resolution measurements
taken near periapsis in the night side.  the isolated
impulsive signals may well be associated with detection of
lightning.  It is also possible that the more continuous
enhancements in the high-frequency-wave channels represent
detection of ion acoustic waves associated with currents
flowing near the bottom of the ionosphere.  Many other
examples of Orbiter plasma wave measurements are contained
in a number of additional reports [2], and these papers
should be consulted for more comprehensive discussions of
the wave observations.

Fig. 5 shows that near the shock the plasma wave instrument
readily detects mid-frequency waves that we identify as ion
acoustic waves (730 Hz and 5.4 kHz), and high-frequency
upstream waves (30 kHz) that are thought to be electron
plasma oscillations associated with superthermal electrons.
The 100-Hz activity shown here probably represents
electromagnetic whistler mode turbulence.

Even in sunlight, the minimum detectable field strengths are
close to the intrinsic threshold levels for the various
channels.  We find electric field spectral densities in
units of (volts/meters)2/(hertz) to be about 1.2 x 10 to the
-10 at 100 Hz; 1.3 x 10 to the -11 at 730 Hz, 8.8 x 10 to
the -13 at 5.4 kHz, and 3 x 10 to the -13 at 30 kHz.  In
terms of equivalent sine waves, these in-flight thresholds
are approximately 30 to 60 mu V/m.  The instrument is
capable of detecting signals up to 90 dB above these minimum
levels before reaching saturation, but no very strong
signals of this nature have ever been detected.

The noise levels given above are nominal values.  Actual
noise levels depend on the location of the spacecraft.
Noise levels are highest and most highly structured when
the spacecraft is in sunlight.  The noise is spin mod-
ulated, with the worst noise occurring in the 100 Hz channel.
Noise is reduced in the ionosphere, and in the optical
shadow.

In the above object no values are given for the
minimum, maximum and noise levels, since these are
different for each channel.  The minimum and maximum
signal levels can be obtained from the scaling law
given in the instrument calibration section, setting
V=0 for minimum and V-5 for maximum.  The nominal on
orbit noise levels are discussed in the instrument
sensitivity section.

For each channel the output Automatic Gain Controller 
(AGC) voltage V (range 0-5 V) is related to the input
wave electric field amplitude E (in V/m/root(Hz))
through the scaling law

  E=a exp (bV)
  
   where:
          a = 5.6938 X 10^-6   b = 2.1267  at 100 Hz 
          a = 2.1987 X 10^-6   b = 1.9676  at 730 Hz
          a = 6.9938 X 10^-7   b = 1.9010  at 5.4 kHz
          a = 2.7058 X 10^-7   b = 1.9094  at 30  kHz 
	  
Acknowledgement

We thank J. Atkinson and E. Vrem for their invaluable
assistance with the design, fabrication, testing, and
integration of the Orbiter Electric Field Detector.  We are
grateful to C. Hall and the staff of the Pioneer Venus
Project at NASA Ames Research Center and Hughes Aircraft
Company for their excellent support, and we especially
acknowledge the continuing assistance of E. Tischler and W.
Hightower.

References

[1] F.L. Scarf, G.M. Crook, I.M. Green, and P.F. Virobik,
    "Initial results of the Pioneer 8 VLF electric field
    experiment", J. Geophys. Res., vol. 73, p. 6665, 1968.

[2] F.L.Scarf, I.M. Green and G.M. Crook, "The Pioneer 9 electric
    field experiment :  Part 1", Cosmic Electrodynamics, vol. 1,
    p. 496, 1971.

[3] F.L. Scarf, W.W.L. Taylor, and I.M. Green, "Plasma waves
    near Venus:  Initial observations", Science, vol. 203, p.
    748, 1979.

[4] W.W.L. Taylor, F.L. Scarf, C.T. Russell, and L.H.
    Brace, "Evidence for lightning on Venus", Nature, vol. 279,
    p. 614, 1979.

[5] W.W.L. Taylor, F.L. Scarf, C.T. Russell, and
    L.H. Brace, "Absorption of whistler mode waves in the
    ionosphere of Venus", Science, vol. 205, p. 112, 1979.