IEEE Transactions on Geoscience and Remote Sensing
   January, 1980      Volume GE - 18     Number 1    ISSNO196-2892
     Special Issue on Instrumentation for the Pioneer Venus Spacecraft
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Pioneer Venus Orbiter Planar Retarding Potential Analyzer
                     Plasma Experiment

William C. Knudsen, Karl Spenner, Jack Bakke, and Vit Novak

                          Abstract

The retarding potential analyzer (RPA) on the Pioneer Venus
Orbiter Mission measures most of the thermal parameters
within and near the Venusian ionosphere.  Parameters include
total ion concentration, concentrations of the more abundant
ions, ion temperatures, ion drift velocity, electron
temperature, and low-energy (0-50 eV) electron distribution
function.  Several functions not previously used in RPA's
were developed and incorporated into this instrument to
accomplish these measurements on a spinning spacecraft with
a small bit rate.  The more significant functions include
automatic electrometer ranging with background current
compensation; digital, quadratic retarding potential step
generation for the ion and low-energy electron scans; a
current sampling interval of 2 ms throughout all scans;
digital logic inflection point detection and data selection;
and automatic ram direction detection.

                      I.  Introduction

The planar retarding potential analyzer (RPA) designed and
developed for the Pioneer Venus Orbiter Mission is an
instrument of advanced design benefitting from steady
progress in planar RPA design over the past approximately
twenty years of the space age [1] - [8].

It measures most of the essential plasma quantities required
to define the state and motion of the ionospheric plasma,
and also measures the temperature and concentration of the
solar wind electrons.

The Pioneer Venus Mission is described in some detail
elsewhere and will not be repeated here [9], [10].  The RPA
repeatedly enters the ionosphere of Venus aboard the
spinning orbiter spacecraft, and measures ionospheric plasma
quantities of the solar-wind-ionosphere interaction region
in the energy range 0-50 eV.

The quantities measured by the orbiter RPA are electron
temperature Te, total ion concentration Ni, individual ion
temperature Tji of the most abundant species, their
concentration Nji, thermal ion drift velocity D, and energy
distribution of suprathermal electron and ion fluxes f(E) up
to 50 eV.  Table I summarizes these quantities and gives the
expected spatial resolutions, ranges, and uncertainties.

       II.  Instrument Principles and Characteristics

Fig. 1, a photograph of the assembled RPA, illustrates the
sensor surrounded by a 30-cm diameter ground plane.  Fig. 2
shows the RPA integrated with the Pioneer Venus orbiter
spacecraft.  An alignment fixture is covering the sensor
grids in this latter photograph.  The planar sensor consists
of a sequence of grids as shown in Fig. 3.  The physical
quantities can be derived for a plasma from the integral
flux of ions or electrons, gathered by collector C, as a
function of energy.  Only particles whose energy is greater
than the retarding voltage applied on the retarding grid G2
can strike the collector.  Use of appropriate voltage
programs allows analysis of the particle energy.  The other
grids and the collector are biased with control voltages
which separate positive and negative particles and minimize
secondary electrons produced by particle impact and photons.

The orbiter RPA operates in three principal modes, a
thermal electron mode, an ion mode, and a suprathermal
electron mode.  The control voltages and retarding potential
programs for these modes are defined in Tables II and III.
The principal modes with different operating options are
selected through ground command.

                    III.  Electron Mode

In the electron mode, the ion current to the collector is
negligible with the collector at 47 V.  A potential
difference of 20 V between G4 and C was found sufficient to
suppress most of the secondary electrons produced by ion or
electron impact at the collector.  The three front grids G0,
G1, and G2 are the energy analyzing grids.  They are stepped
together from +6.8 to -4.2 V in the coarse scan.  The
corresponding collector current is measured by a logarithmic
electrometer and then digitized.  Fig. 4 illustrates a
characteristic curve returned by the RPA while operating in
the electron mode with I-V option.  The straight-line
portion of the characteristic curve in which the logarithm
of the current is proportional to the retarding potential is
the retarding region, and the shape of the straight line
determines the electron temperature by the relation

       e      D V
Te = - -  ------------
       k   D log (-Ie)

where e is the electron charge; k the Boltzmann constant;
and Ie the electron current.  The left side with larger
positive voltage is the attractive region.  The voltage Vp
at which these two portions of the curve join is the
potential of plasma relative to spacecraft.  Within the
ionosphere, it has been varying from a few tenths volt
negative to three volts positive.  At the lower end of the
retarding region, the current decreases more slowly with an
increase in retarding potential than it did in the retarding
region because of a population of ambient photoelectrons
with high energy.  The strong decrease in current at the end
of the retarding voltage range results from the presence of
a compensating current added by the RPA instrument.  At the
maximum retarding voltage of each mode, the RPA adds current
of the appropriate sign and magnitude to the electrometer
input to decrease the absolute value of the total current to
less than approximately 2 x 10-12 A [8].  This current
compensation reduces the influence of high-energy particles
and photo-electrons produced within the RPA by solar
radiation of the measurement of thermal plasma quantities.

The RPA is usually operated in a "peak option" state in
which the retarding region is automatically recognized by
the RPA, and either 5 or 11 values of D log (-Ie)(=log +
(Ie,J/Ie,J+1))  spaced around the retarding region are
selected depending on command option and returned to earth.
Onboard logic forms the first and second finite differences
of the successively digitized values of log (-Ie).  When a
sequence of these values satisfy a peak criterion, the logic
selects 5 or 11 values of D log (-Ie) about the peak and the
retarding potential step number for transmission to earth.
Values of D log (-Ie) selected and returned from Venus by
the RPA are illustrated in the lower portion of Fig. 4.  The
retarding voltage step program in the "peak option" consists
of a coarse scan over the entire voltage range followed by
one or three fine scans over the appropriate subrange
centered where the largest difference in the coarse mode has
occurred (Table III).  The D log (-Ie) values measured in the
fine scan have been multiplied by four for proper comparison
with the values measured in the coarse scan.  The retarding
voltage at which the largest value of D log (-Ie) occurs in
the coarse electron scan is quite close to the plasma
potential and is used as the starting potential (reference
potential) for the quadratic ion retarding potential step
program.

The purpose for the coarse and fine electron retarding scan
is to measure a large range of temperatures.  The RPA has
operated successfully in the thermal-electron peak mode from
300 to 25 000 K.  Temperatures above approximately 25 000 K
are measured in the suprathermal electron mode.

                       IV.  Ion Mode

With the collector at -4.6 V and suppressor grid at -24.6 V,
ambient electrons with energy less than approximately 24.6
eV are not collected.  Ions with sufficient kinetic energy
to overcome the retarding potential on grid G2 (Fig. 3) are
collected.  An ion-characteristic curve measured by the RPA
in the Venus ionosphere is illustrated by the dots in Fig.
5.  The retarding potential V is related to the step
lettered J by the equation

                J (j - 1)
VJ - V ref =  ___________  0.011 V
                   2

where V ref is a voltage close to the plasma potential
sensed and established in the electron mode.  The current
corresponding to every other step value is returned by the
RPA when operating in the ion mode with I-V option.  The
solid line is the least square fit of the appropriate
theoretical expression for the total current to the data
points [8].  The derived quantities are listed in the
figure.

When operating in the "peak option" the RPA forms difference
in current delta IJ(=IJ-IJ+1) measured at successive
retarding potential steps and returns either 5 alternate or
11 successive values of delta IJ around sensed peaks in
delta I.

Examples of delta I values returned around 0+ and 0+2 peaks
are also illustrated in Fig. 5.  The same digital peak
criterion is used to recognize the ion peaks as is used to
recognize the retarding region of the electron
characteristic curve.  It is shown elsewhere [8] that the
delta I values about peak are approximately Gaussian in
shape.  The half-width of the peaks is proportional to the
square root of the ion temperature Ti, and the peak value of
delta IJ is proportional to the ion concentration divided by
square root Ti.  The value of J at which the peak occurs is
proportional to the square root of the ion kinetic energy
normal to the RPA grids.  The ion temperature,
concentration, mass, and velocity normal to the RPA grids
are derived by numerically fitting the theoretical
expression for delta IJ to the measured values of delta IJ
with use of the least squares criterion.  The solid curve in
the lower-half of Fig. 5 is drawn through the theoretical
values of delta IJ.  The geophysical quantities derived from
the fit are listed.  In computing the theoretical values of
delta IJ (and also IJ), an ion mass 13 was assumed present
with a concentration equal to 7 percent of the 0+
concentration.

               V.  Vector Ion-Drift Velocity

Vector ion-drift velocity is measured by measuring three
single components of the velocity in three different
directions.  Fig. 6 illustrates the principle of measurement.
From the analysis of data from a single sweep of the RPA,
the component of total ion velocity normal to the RPA grids
is derived.  A single sweep of the RPA requires
approximately 0.16 s during which time the spacecraft
rotates through 5 degrees about its spin axis.  The
telemetry bit rate assigned to the RPA permits only one
sweep of data to telemetered to earth per spacecraft spin
period.  Consequently, to achieve a vector measurement of
the ion-drift velocity, one sweep of data is recorded in
each of three successive spin periods at three different
roll angles.  With the RPA measurement axis offset from the
spin axis by 25 degrees the necessary three independent
components measurements are achieved.  The first ion sweep
designated I1 is recorded when the total ion velocity
relative to the spacecraft lies in or close to the plane
defined by the spacecraft spin axis and the RPA period 45
degrees in roll angle before that at which I1 was recorded.
Sweep I3 is recorded in the third spin period at a roll
angle 45 degrees greater than that at which I1 was recorded.

The roll angle at which I1 is recorded is defined by receipt
of a "Ram" signal from the spacecraft or by sweep with
largest saturation ion current.

              VI.  Supra Thermal Electron Mode

The collector and guard ring are biased at +47 V in the
suprathermal electron mode to collect electrons and the grid
G1 is biased at +47 V to prevent positive ionospheric ions
from impinging on the retarding grid G2 [11].  The retarding
grid G2 is stepped quadratically from 0 to -50 V during
which time the electron currents are digitized for
telemetering to earth.  The RPA may be programmed to record
one suprathermal-electron characteristic curve every fifth-
spin revolution, the other four revolutions being used to
record one thermal-electron sweep followed by three ion
sweeps, or it may be programmed to record one suprathermal-
electron sweep every spin revolution with successive sweeps
spaced 90 degrees in roll angle from each other.  In this
latter mode of operation, only suprathermal-electron data
are recorded.

The electron energy distribution function fe is derived from
the set of electron currents with use of the Druyvesteyn
[12] relation:

        V       d2I
fe = _______   _____
      e2        dV2

In regions of space where the electron energy distribution
is expected to be Maxwellian, the parameters of the
Maxwellian distribution, temperature, and concentration are
derived by fitting a straight line to the curve of log Ie
versus V.

Fig. 7 shows an example of the suprathermal-electron
currents measured in the dayside ionosphere and the derived
electron-energy distribution.

                VIII.  Inflight Calibration
                              
The RPA is commanded periodically into an inflight
calibration sequence.  In the first part of the sequence,
the electrometer is disconnected from the collector and a
sequence of internal calibration currents satisfying the
peak selection criteria are applied to the electrometer to
evaluate the electrometer sensitivity and peak selection
logic.  In subsequent portions of the calibration sequence,
the internal noise of the electrometer in its most sensitive
range is measured, and the retarding voltages are sample to
verify amplifier gain and proper logic operation.

            VIII.  Instrument Parameter Summary

The following table summarizes the more important physical
and electrical properties of the RPA.

IX.  Conclusions

The Pioneer Venus orbiter RPA is measuring a large number of
the plasma quantities needed to define the state and motion
of the ionospheric plasma.  These measurements are
contributing to a detailed definition of the ionosphere and
to an understanding of the processes affecting it [13] -
[15].  Measurements from the suprathermal-electron mode are
contributing to the detailed definition of the ionosheath,
ionosphere and mantle plasmas, and the boundaries separating
them [16].  The RPA is an instrument of advanced design and
has been operating continuously and as designed for
approximately fifteen months since launch at the time of
preparation of the manuscript. (Aug. 1979).

                       Acknowledgment
                              
We wish to acknowledge the dedicated efforts of many people
who contributed to the development of the orbiter RPA.
Special mention should be made of Dr. J. Reagan, S.
Bjerklie, J. McDaniel, V. Waltz, J. Parker, and K. Fong of
the Lockheed Palo Alto Research Laboratory, W. Ott of the
Institut fur Physikalische Weltraumforschung, K. Polzer, G.
Kupfahl, E. Eichhorn, H. Bauer, V. Gerber, K. Sudholt, A.
Kronthaler, and E. Spermann of Messerschmitt-Bolkow-Blohm
GmbH, Mr. Guenther and Dr. Klinkman of DFVLRIBPT, and E.
Tischler and A. Wilhelmi of NASA/AMES.

The financial support for W.. Knudsen, J. Bakke, and the
Lockheed Palo Alto Research Laboratory for the development
of the control electronics subassembly and integration of
the instrument of the spacecraft was provided by NASA.  The
financial support for K. Spenner, V. Novak, the Institut fur
Physikalisches Weltraumforschung and Messerschmitt-Bolkow-
Blohm GmbH for the development of the sensor subassembly and
its electronics was provided by the Bundesminister fur
Forschung und Technologie of the Federal Republic of West
Germany.

                         References

[1]  H. E. Hinteregger, "Combined retarding potential
analysis of photoelectrons and environment charge particles
up to 234 km," Space Res., vol. 1, pp. 304-327, 1960.

[2]  W. B. Hanson and D. D. McKibbin, "An ion trap measurement
of the ion concentration profile above the F2 peak," J.
Geophys. Res., vol. 66, pp. 1667-1671, 1961.

[3]  W. C. Knudsen, "Evaluation and demonstration of the use
of retarding potential analyzers for measuring several
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4669-4678, 1966.

[4]  K. K. Harris, G. W. Sharp, and W. C. Knudsen, "Ion
temperature and relative ion composition measurements from
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[5]  W. B. Hanson, S. Sanatani, D. Zuccaro, and T. W.
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[6]  W. B. Hanson, D. R. Zuccaro, C. R. Lippincott, S.
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[7]  K. Spenner and A. Dumbs, "The retarding potential
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[8]  W. C. Knudsen, K. Spenner, J. Bakke, and V. Novak,
"Retarding potential analyzer for the Pioneer-Orbiter
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[9]  L. Colin and C. F. Hall, "The Pioneer-Venus program,"
Space Sci. Rev., vol. 20, pp. 283-306, 1977.

[10]  L. Colin, "Encounter with Venus," Science, vol. 203,
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[11]  W. C. Knudsen and K. K. Harris, "Ion-empact-produced
secondary electron emission and its effects on space
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1973.

[12]  M. J. Druyvesteyn, "Der Niedervoltbogen," Z. Phys.,
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[13]  W. C. Knudsen, K. Spenner, R. C. Whitten, J. R. Spreiter,
K. L. Miller, and V. Novak, "Thermal structure and major ion
composition of the Venus ionosphere:  First RPA results from
Venus orbiter," Science, vol. 203, pp. 757-763, 1979.

[14]  __, "Thermal structure and energy influx to the day
and nightside Venus ionosphere," Science, vol. 205, pp. 105-
107, 1979.

[15]  W. C. Knudsen, K. L. Miller, K. Spenner, R. C. Whitten,
and J. R. Spreiter, "Ion drift velocity measurements in the
Venusian ionosphere," in Abstract, EOS, vol. 60, p. 303,
1979.

[16]  K. Spenner, W. C. Knudsen, K. L. Miller, and V. Novak,
"Observations of the Venus ionospheric mantle formed between
ionosphere and ionosheath," in Abstract, XVIIth General
Assembly of the Int. Union Geodesy and Geophysics (Canberra,
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