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      Pioneer Venus Orbiter Fluxgate Magnetometer

C.T. Russell, R.C. Snare, J.D. Means, and R.C. Elphic

  IEEE Transactions on Geoscience and Remote Sensing,
                  January 1980.
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Abstract

The Earth's atmosphere is shielded from the solar wind, the
rapidly expanding ionized gas of the sun's outer corona, by
a moderately strong magnetic field generated by a dynamo
inside the liquid core of the earth.  That Venus is not thus
shielded was evident from the measurements of the earliest
probes to Venus [1], [2].  It was not certain that these
measurements indicated that Venus had no intrinsic field.
Rather, the existence of a small intrinsic field was still
possible [3], and in fact expected from dynamo models [4].
A measure of the size of any Venus moment would be a check
on our understanding of planetary dynamos.  Furthermore, the
solar wind was thought to interact directly with the upper
atmosphere of Venus, a situation quite unlike that probed on
other planetary missions. (Mars may have a similar
interaction with the solar wind, but Martian studies have
concentrated on the surface and lower atmosphere rather than
the upper atmosphere.)  Such an interaction is only poorly
understood.  It is possible that the weak magnetic field of
the solar wind could act to shield the upper atmosphere by
inhibiting the solar wind penetration into the atmosphere.
Thus it was important for both aeronomical and
planetological reasons to measure the magnetic field in the
near vicinity of Venus.  Only from an orbiter with a
controllable periapsis altitude could the requisite series
of low-altitude measurements be made.

The intent of the Pioneer Venus mission was to be both
comprehensive and low cost.  The former requirement led to
the inclusion of a large number of instruments and the need
for a moderately high data rate and hence a despun antenna.
The latter requirement led to a spinning spacecraft, a
minimum magnetic cleanliness program and no allowance for
redundancy.  Even with a despun antenna the Pioneer Venus
spacecraft would sometimes have to transmit data at rates as
low as 8 bits/s when Venus was on the far side of the sun
and the deep space net telemetry stations were being used
for outer planet missions.  These constraints made for some
exacting design challenges both for the spacecraft design
team and the magnetometer team.

System Design

Since the spacecraft designers were attempting to maximize
the use of off-the-shelf hardware from programs without a
need for magnetic cleanliness, the decision was made earlier
in the program to place the sensors as far away from the
center of the spacecraft as possible (approx. 5 m).  Since
there would be moderately high thrust at orbit injection and
interplanetary measurements and deployment of the
magnetometer were needed before orbit injection, the boom
for the magnetometer was made rigid.  This rigid boom was
stowed in three hinged sections on top of the spacecraft and
deployed by centrifugal force shortly after launch and
interplanetary insertion.

A magnetic field is a vector quantity which can be specified
by a magnitude and two angles or the three orthogonal
components of the vector.  At any instant of time this
measurement requires three orthogonal detectors.  On a
spinning spacecraft, if the external field remains steady
and the spacecraft field and internal instrument zero levels
are accurately known, a single sensor tilted with respect to
the spin axis will suffice.  There will be a sine wave whose
amplitude and phase, relative to some direction in space
such as the sun, give the two components of the field in the
spin plane.  The average over a spin period gives a measure
of the field along the spin axis.  Although conditions of
sufficiently steady field are frequent in the vicinity of
Venus, the interesting regions are where the field values
change rapidly.  Thus three sensors were deemed necessary.

The despun antenna assembly was expected to be magnetic as
were several other subsystems.  Furthermore, it was possible
that these fields might change during the mission.
Monitoring the field at two radial distances would help
monitor such changes through the differences between the two
readings if the sensors gains and zero levels remained
constant.  While this feature was desirable it was not
affordable within the weight and power allowance of the
magnetic fields investigation.  A compromise design was to
take one of the sensors from the triad on the end of the
boom and install it 1/3 of the way back along the boom
tilted with respect to the satellite spin axis and at right
angles to the sensor in the spin plane.  At low frequencies,
well below the spacecraft spin frequency, this provided two
measures of the field at varying distances from the
spacecraft subject to the limitations discussed above.  At
high frequencies, at which interference was expected to be
minimal, the readings could be combined to give the
equivalent readings of three mutually orthogonal sensors.
Not only did this approach provide a rudimentary
gradiometer, but also reassuring redundancy.  Only the
failure of two sensors would have prevented the measurements
of three components of the magnetic field.  No single sensor
failure would have jeopardized the measurement.

Our next design challenge was the problem of the occasional
very low telemetry rates.  At 8 b/s, we would obtain only
one vector sample of the magnetic field every 21 or 64 s
depending on which telemetry format was being used.  Since
the spin period of the spacecraft was 12 s these low data
rates were insufficient to enable the amplitude and phase of
the signal from the sensors with components in the spin
plane to be determined.  Thus it was necessary to 'despin'
the measurements to an inertial frame before transmittal.
The optimum despinning routine would be to multiply the data
by sine and cosine waves in phase with the rotation and
average over an integral number of spin periods.  Again
weight and power were not available for the optimum approach
and we used a Walsh transform rather than a Fourier
transform.  The Walsh transform is basically the
multiplication of the data by two square waves in quadrature
at the spin period.  Overlapped averages are accumulated in
six averaging registers, half of which were read out one
telemetry cycle and the other half the next.  There are 64
samples in each average which could be spread over 1, 2, or
4 spins, resulting in overlapped samples being returned
every 1/2, 1, or 2 spins or every 6, 12, or 24 s.  Thus at
the lowest bit rate, 8 b/s, when the telemetry format is
returning a vector every 21 s, accurate vector measurements
are obtained.

As mentioned above, well below the spin frequency one can
determine the two components of the field in the spin plane
from one sensor with a component in the spin plane.  Thus in
normal operation at low bit rates (called NORMAL MODE) the
instrument performs a Walsh transform on only the outboard
sensor in the spin plane (called the T sensor).  The in phase
average of T and quadrature average of T are stored along
with the usual average of the readings from the outboard
sensor parallel to the spin axis (the P sensor).  This
scheme provides only a measure of the field at the outboard
sensor.  Another operating mode (Gradiometer mode) was
included to provide in-phase and quadrature transforms and a
regular average of the inboard G sensor.  In the Gradiometer
mode all rates remain the same.  The only difference is that
the G sensor averages are stored in the second set of three
averaging registers at the expense of overlapped averages.

To obtain both the desired range (+/- 128 nT) and resolution
(+/- 1/16 nT), a 12-bit analog-to-digital conversion was
used.  To optimize the utilization of the available
telemetry, 32 bits per vector sample, two of the 12-bit
samples were converted to floating point words consisting of
an eight-bit mantissa and a two-bit exponent by checking the
leading bit for zeros and shifting bits if the leading bit
was zero.  A maximum of three shifts was permitted.  The
number of shifts formed the exponent.  Thus these two
measurements had resolution of +/- 1/2 nT when the reading
was greater than 64 gamma in magnitude changing to +/- 1/16
nT when the reading was less than 16 nT.

It is necessary to limit the bandwidth of the magnetometer
so that signals of frequency too high to be resolved by the
telemetry system, do not enter the sampling circuitry.  The
maximum frequency that can be properly analyzed is half the
sampling frequency and is called the Nyquist frequency.  If
signals enter the telemetry stream at frequencies above the
Nyquist frequency they appear to occur at a frequency below
their true frequency.  This process is called aliasing and
the filters in the instrument that prevent this are called
aliasing filters, although a more proper name would be
nonaliasing filters.  Since the telemetry rate of the
spacecraft varied over an enormous range, the corner
frequency of the aliasing filters too had to vary.  These
corner frequencies were controlled automatically according
to the instrument sample rate.  Depending on the telemetry
format the instrument could sample once per minor frame (512
bits) or three times.  These modes were called SLOW sampling
and FAST sampling, respectively.  At telemetry rates of 512
b/s and below the corner frequency was kept fixed at 0.2 Hz.
The resultant sample rates and 3 dB points are given in
Table 1.  When the sample rate drops below 0.5 Hz, onboard
averaging is generally used.

                       Table 1
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Pioneer Venus Orbiter Sample Rates and Corner Frequencies
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Spacecraft    Slow  Sample  Mode    Fast  Sample  Mode
Telemetry      Sample    Corner      Sample   Corner 
Rate (bps)     Rate(Hz)  Freq.(Hz)   Rate(Hz) Freq.(Hz)
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 2048          4          1.8         12       4.5
 1024          2          0.4         6        3.0
 683           1.33       0.2         4        2.5
 512           1          0.2         3        0.2
 341           0.67       0.2         2        0.2
 256           0.5        0.2         1.5      0.2
 171           0.33       0.2         1        0.2
 128           0.25       0.2         0.75     0.2
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Since the spacecraft was to undertake a lengthy trip in
space (over 6.5 months) before making its prime measurements
and since a long useful lifetime of the spacecraft was
anticipated, a commandable calibration signal was included.
The signal is a dc current applied to an external winding
surrounding each sensor so that the readings changed by
approximately 40 nT.  The current is applied for a telemetry
major frame which is 64 minor frames.  During a minor frame
the magnetometer is read out either once or three times.
The reference voltage in the instrument's 12-bit analog-to-
digital converter is used to power the calibrate signal.
Since this voltage also is the reference for the
digitization of the signal only a change in the analog
circuitry will result in variations in the apparent size of
the calibrate signal.  To check the invariance of the
reference voltage, it is digitized by the spacecraft analog-
to-digital converter and telemetered to earth.

The Basic Magnetometer

The basic magnetometer has been described by Snare and Means
[5] and is similar in many respects to the ISEE-1 and 2
magnetometers [6].  Briefly it is a fluxgate magnetometer
with large loop gain and feedback.  The sensors are ring
core types manufactured by the Naval Surface Weapons
Laboratory, White Oak [7].  The drive voltage is a very
clean 7.25-kHz sine wave with an amplitude of about 4-V peak-
to-peak.  The drive current is approximately 159 mA.  The
detected signal is the second harmonic of the drive
frequency, detected in a double sideband suppressed carrier
mode.  The open-loop gain is unity at 300 Hz and approaches
10 to the 8 at dc.  The closed-loop system response is flat
with a first-order corner at 300 Hz.

Construction

The basic magnetometer uses integrated-circuit operational
amplifiers mounted on a two-sided printed circuit board.
The digital circuit are all CMOS integrated circuits mounted
on stitch wired boards.  The electronic assembly chassis is
all magnesium.  Sensor assemblies were machined from epoxy
fiberglass stock.  Conceptual and preliminary design was
performed at UCLA with detailed design and fabrication at
Westinghouse Electric Company, Baltimore, MD.

The electronic unit mounted on the main body of the
spacecraft measures 15 X 22 X 15 cm and weighs 1.7 kg.  The
inboard sensor assembly measures 6 X 7 X 6 cm and weighs
100g.  The outboard sensor assembly measures 8 X 5 X 4.4 cm
and weighs 170 g.  The total power required is 2.2 W at 22-V
dc.

The sensors are mounted at the end of a 5 meter boom.  The
boom is radially extended from a point 240 degrees counter-
clockwise (direction of spacecraft spin) around from the
x-axis of the spacecraft (looking down) on the side with
the despun antenna and instruments.  The sun sensor is about
355 degrees measured in this coordinate system so that the
boom is 115 degrees behind the sun sensor.  The T sensor
points perpendicular to the boom axis.

Initial Operation

The magnetometer was turned on shortly after launch and has
operated continuously since that time except for brief
periods at orbit injection and during the long eclipse
season.  The instrument has operated flawlessly.  Daily
checks of the instrument calibration show no change in gain
in over one year's operation in space.

Despite the fact that Venus had been probed many times
before, including two Soviet orbiting vehicles, much has
been learned during the first year's operation.  We will
start in the solar wind and work inwards to the planet
rather than attempt to prioritize the findings.  First, the
bow shock, which stands in front of the planet and deflects
and heats the supersonic solar wind when it encounters the
planetary obstacle, is significantly further out now than it
was in 1975 when the shock was probed by the Venera 9 and 10
orbiters [8].  This suggests that there has been a change in
the Venus ionosphere since then as the solar cycle
progressed towards solar maximum.  Second, the bow shock is
much weaker than the terrestrial bow shock [9].  The
phenomenon could be caused by slowing down of the solar wind
before it reached the bow shock by mass addition from the
Venus hydrogen geocorona, or by absorption of solar wind by
the upper atmosphere of Venus.  Third, the shock does not
appear to be asymmetric about the solar wind flow direction
as reported earlier from a more limited set of Venera bow
shock crossings [10].  Fourth the ionopause, the upper limit
of the ionosphere, appears to be a tangential discontinuity
with approximate pressure balance maintained between the
thermal pressure of the electrons and ions in the ionosphere
and the magnetic field external to the ionosphere [11].  The
magnetic field strength in the ionosphere is generally very
low [12].  Fig. 1 shows the magnetic field strength on four
successive passes through the ionosphere.  Most often low
field regions interspersed with narrow twisted filaments of
field or flux ropes [13] are observed.  Occasionally a more
steady field is found as in orbit 163.  Finally, we have not
yet found any evidence for a planetary field.  The upper
limit to the Venus magnetic dipole moment is now much less
than theoretical expectations [14].

Acknowledgement

The success of this investigation is due to the effort of a
large number of individuals.  At UCLA we are particularly
grateful to F.R. George and B. Greer who assisted in the
design and fabrication of the ground support equipment and
testing of the instrument.  At Westinghouse the final design
and fabrication was skillfully directed by A. Plitt.  We
benefitted much from the advice and guidance of M. Larson of
ONR, and D. Sinnott and E. Tischler of Ames, and appreciate
the excellent spacecraft provided by the Ames Research
Center - Hughes Aircraft team led by C.F. Hall and S.
Dorfman, respectively.  Special thanks go to E. Iufer and R.
Murphy of the Ames Research Center for their assistance in
calibrating the magnetometers.

References

[1] E.J. Smith, L. Davis, Jr., P.J. Coleman, Jr., and C.P.
    Sonett, Science, vol. 139, p. 909, 1963.

[2] Sh. Sh. Dolginov, Ye. G. Yeroshenko and L. Davis, 'On the
    nature of the magnetic field near Venus,' Kosmich. Issled.,
    vol. 7, p. 747, 1969.

[3] C.T. Russell, 'The magnetic moment of Venus:  Venera-4
    measurements reinterpreted,' Geophys. Res. Lett., vol. 3, p.
    125, 1976.

[4] F. Busse, 'Generation of planetary field by convection,'
    Phys. Earth Planet. Int., vol. 12, p. 350, 1976.

[5] R.C. Snare and J.D. Means, 'A magnetometer for the Pioneer
    Venus mission,' IEEE Trans. Magnetics, vol. MAG-13, p. 1107,
    1977.

[6] C.T. Russell, 'The ISEE-1 and 2 fluxgate magnetometers,'
    IEEE Trans. Geosci. Electron., vol. GE-16, p. 239, 1978.

[7] D.I. Gordon and R.E. Brown, 'Recent advances in fluxgate
    magnetometry,' IEEE Trans. Magnetics, vol. MAG-8, p. 76,
    1972.

[8] J.A. Slavin, R.C. Elphic, and C.T. Russell, 'A comparison of
    Pioneer Venus and Venera bow shock observations:  Evidence
    for a solar cycle variation,' Geophys. Res. Lett., 1979.

[9] C.T. Russell, R.C. Elphic, and J.A. Slavin, 'On the strength
    of the Venus bow shock,' Nature, in press, 1979.

[10] J.A. Slavin, R.C. Elphic, C.T. Russell, J.H. Wolfe, and D.S.
     Intriligator, 'Position and shape of the Venus bow shock:
     Pioneer Venus orbiter magnetometer observations,' Geophys.
     Res. Lett., 1979.

[11] R.C. Elphic, C.T. Russell, J.A. Slavin, L. Brace and A.
     Nagy, ' The location of the dayside ionopause of Venus:
     Pioneer Venus Orbiter magnetometer observations,' Geophys.
     Res. Lett., submitted, 1979.

[12] C.T. Russell, R.C. Elphic, and J.A. Slavin, 'Initial Pioneer
     Venus magnetic field results: Dayside observations,'
     Science, vol. 203, p. 745, 1979.

[13] C.T. Russell and R.C. Elphic, 'Observation of magnetic flux
     ropes in Venus ionosphere,' Nature, vol. 279, p. 616, 1979.

[14] C.T. Russell, R.C. Elphic, and J.A. Slavin, 'Initial Pioneer
     Venus magnetic field results:  Nightside observations,'
     Science, vol 205, p. 114, 1979.