Winds on Titan: First results from the Huygens Doppler
Wind Experiment
Supplementary Discussion.
    It was realized during the DWE design phase that Earth-based Doppler 
measurements could be combined with the orbiter Doppler measurements to 
reconstruct both the zonal and meridional components of the Huygens probe
motion during descent.   
Ideally, the horizontal projections of the Huygens-to-Cassini and 
Huygens-to-Earth ray paths should be perpendicular for this purpose, but the 
160 deg separation for the actual experiment geometry was considered adequate 
for the calculation. A fundamental uncertainty in the Earth-based measurement 
was whether the received power from the Huygens carrier signal would be 
sufficient to support near real-time reduction of the data, or a more 
extensive data processing effort, augmented with additional information from
the telemetry sub-bands, would be required. This latter procedure was  
necessary, for example, in the case of the ground-based detection of the 
Galileo Probe signal at Jupiter (Folkner et al. 1997).   In spite of the 
considerably greater distance, the probability for detecting the Huygens 
signal from Titan was deemed slightly more favorable than for the case of the 
Galileo Probe.  The primary factors leading to this conclusion were the 
considerably higher Huygens transmitter antenna gain toward Earth as well as
the presence of significant residual carrier power in the Huygens signal as 
opposed to no residual carrier for the Galileo Probe. As a result, 
preparations were undertaken to establish an Earth-based network of radio 
telescopes that would record the frequency of the Huygens Ch. A signal during 
the Titan descent. Two essential telescope selection criteria were: (a) 
capability of receiving the Huygens 2040 MHz signal, and (b) sufficient 
elevation above the local horizon for visibility of Titan during the Huygens
mission.  
A second Earth-based experiment designed to provide ultra-precise sky  
positions of the Huygens probe using the technique of Very Long Baseline 
Interferometry (VLBI) was developed over the latter years of the 
interplanetary cruise phase (Gurvits 2004; Pogrebenko et al. 2004). The 
results of the VLBI experiment, which enlisted a total of 17 radio telescopes 
in Australia, China, Japan, and the USA, are to be described elsewhere. 
Together, the VLBI and Earth-based Doppler experiments constituted the radio
astronomy segment of the Huygens mission. A joint observation proposal was 
submitted to the National Radio Astronomy Observatory (NRAO), specifically for
observation time at the Robert C. Byrd Green Bank Telescope (GBT) in West 
Virginia, and at eight antennas of the Very Long Baseline Array (VLBA), and to
the Australia Telescope National Facility (ATNF) for observations at the 
Parkes Radio Telescope and several other smaller Australian antennas.
Six of the 17 radio telescopes participating in the radio astronomy segment of
the Huygens mission conducted Earth-based DWE measurements of the received 
frequency, which, owing to the loss of Ch. A on Cassini, thus comprise the DWE
data base. Supplementary Table 1 lists the six Earth-based DWE stations and 
their respective observation intervals in terms of Earth received time 
(ERT/UTC). The corresponding time at Huygens, the Spacecraft Event Time 
(SCET/UTC), is obtained by subtracting the one-way light time of ~4026.35 s 
(1 h 7 m 6.35 s). Special NASA Deep Space Network Radio-Science Receivers 
(RSRs), designed to support and display radiometric recording of extremely 
narrowband spacecraft signals, were installed for this unique occasion at GBT 
and Parkes. Even for the GBT, the largest available radio telescope for this 
purpose, link budget calculations of the Huygens signal strength predicted a
voltage signal-to-noise ratio of about 3:1 using only the probe carrier signal
(see Supplementary Table 2). Four stations from the VLBA network were also 
equipped to record the Huygens signal pass-band for Doppler analysis. Only the
GBT and Parkes RSR data sets are discussed in this initial report.
The topocentric sky frequency of the Huygens Ch. A carrier signal recorded at 
GBT and Parkes is shown in Supplementary Figures 1-3. Reflecting the velocity 
and pointing direction of the specific receiving antenna, this is the 
frequency actually observed at each ground station. The time resolution is 
typically one point each 10 seconds, for which the measurement error is of the
order of 1 Hz, corresponding to an uncertainty in the line-of-sight velocity 
of 15 cm/s. Supplementary Figure 1 shows all data from both facilities, while 
Supplementary Figures 2 and 3 display higher time resolution data plots 
recorded at GBT and Parkes, respectively. The Earth-based signal detection at 
GBT coincides with the initial transmission from Huygens at t0 + 45 s, where 
t0 is the designated start of the descent at 09:10:20.76 SCET/UTC.   
The small gaps in the GBT and Parkes measurements occur when the telescope 
pointing direction was offset from Huygens to observe a nearby natural radio 
source for purposes of calibrating the Huygens VLBI experiment. This 
observation cycle was repeated every three minutes, of which about 100 s were 
allocated to direct tracking of Huygens. A single larger gap of 26 minutes is 
present in the interval between the end of the observations at GBT and the 
start of observations at Parkes. It is anticipated that this gap will be 
filled largely with Doppler data from the four VLBA stations. Furthermore, 
since two VLBA stations, Pie Town and Owens Valley, did not participate in the
VLBI antenna nodding procedure (Supplementary Table 1), it may be possible to 
fill the gaps within the GBT and Parkes observation intervals. Doppler 
measurements extracted from the VLBI recordings at GBT and Parkes have been 
found to be in excellent agreement (differences typically less than 1 Hz) with
the RSR data. The Doppler shift of the Huygens signal is determined primarily 
by the relative velocity of Titan and Earth. The difference in telescope 
velocity toward Titan due to Earth's rotation is reflected in the frequency 
offset between that seen toward the end of track at GBT and that seen at the 
start of track at Parkes (Supplementary Figure 1). Predictions of the received
frequency are included in Supplementary Figures 2 and 3.  
These were derived from simulations of the Huygens motion during the  
atmospheric descent in the absence of wind (dotted curve) and with a standard 
project engineering wind model (solid line). This latter wind model (Flasar et
al. 1997) features a purely zonal prograde flow, i.e., in the direction of 
Titan's rotation, that increases linearly from zero at the surface to 100 m/s 
at a height of 160 km. The meridional flow is zero in these models. Noting 
that many of the GBT Doppler measurements roughly follow intermediate values 
between the prediction without wind and the prediction with a prograde wind 
(Supplementary Figure 2), it is apparent that the probe must have been
drifting for much of the descent in the same direction as that predicted by 
the project engineering model, but with a slower line-of-sight velocity.   
References to Supplemental Information
Flasar, F.M., Allison, M. & Lunine, J.I. Titan zonal wind model. in Huygens 
Science Payload and Mission, ESA-SP 1177, 287-298 (1997).
Folkner, W.M. et al. Earth-based radio tracking of the Galileo Probe for 
Jupiter wind estimation.  Science 275, 644-646 (1997).
Gurvits, L.I. Christiaan Huygens, Huygens the probe and radio astronomy. in 
Titan: from Discovery to Encounter, ESA-SP 1278, 408-411 (2004).
Pogrebenko, S.V. et al. VLBI tracking of the Huygens probe in the atmosphere 
of Titan. in Planetary Probe Atmospheric Entry and Descent Trajectory Analysis
and Science, ESA-SP 544, 197-204 (2004).


Figure Captions - Supplementary Information
Supplementary Figure 1. Topocentric sky frequencies of the Huygens Ch. A
carrier signal recorded at the GBT and Parkes facilities.  The nominal 
transmit frequency (a constant value of 2040 MHz) has been subtracted, so that
the plotted data points are equivalent to the total signal Doppler shift from
transmitter to receiver.  The upper time scale is Spacecraft Event Time; the
lower scale is minutes past the nominal start of mission at t0 = 09:10:20.76
SCET/UTC. The Earth's rotation is primarily responsible for the lower recorded
frequency at GBT (near end of track) with respect to Parkes (near start of 
track). The small gaps between data segments correspond to intervals when the 
radio telescopes were pointed to celestial reference sources near Titan for 
calibration of the simultaneously conducted VLBI experiment.  The times of 
impact at t0 + 147 m 50 s, (11:38:11 SCET/UTC) and loss of link to Cassini at 
t0 + 220 m 3 s (12:50:24 SCET/UTC) are indicated. The Parkes tracking pass 
ended at t0 + 341 m 37 s (14:51:58 SCET/UTC) with the Huygens probe still 
transmitting from the Titan surface.
Supplementary Figure 2.  GBT frequency measurements from the start of the
Huygens broadcast until end of track.  The recorded data (dots) generally lie
between the predicted Doppler values assuming no winds (thin dotted curve)
and a model with a moderate prograde wind (thin curve).   A clear Doppler
signature for the change from the main parachute to a smaller drogue 
parachute may be seen at t0 + 15 minutes.  At this instant, the suddenly  
larger descent velocity produces an abrupt decrease in the received frequency 
which closely follows that predicted by simulation.
Supplementary Figure 3.   Parkes frequency measurements near the time of 
surface impact.   Actual observations (dots) are compared with predictions  
with wind (thin curve) and no wind (thin dotted curve), respectively. The 
obvious discontinuities in the prediction curves result from the simulated 
impact on Titan at ~11:24 SCET/UTC for this specific model. The actual impact 
at 11:38:11 SCET/UTC occurred during one of the small data gaps when the 
Parkes antenna was pointed away from Huygens. The nearly discontinuous 
increase in frequency at 11:38:11 SCET/UTC marks the impact on the surface. 
The magnitude of this positive jump in frequency, 26.4+/-0.5 Hz, reflects the 
abrupt change in vertical velocity from about 5 m/s to zero.


Supplementary Table 1  Radio telescopes in Earth-based DWE Network
Facility  Diameter (m)  Lat.(deg)  W. Long.(deg)  Start(UTC)  Stop(UTC)  Notes
GBT              100     38.4          79.8        09:31:10   12:15:00     1,2
VLBA Pie Town     25     34.3         108.1        09:30:11   14:15:04       3
VLBA Kitt Peak    25     32.0         111.6        09:31:10   14:15:00       2
VLBA Owens Valley 25     37.2         118.3        09:30:09   14:49:14       3
VLBA Mauna Kea    25     19.8         155.5        09:31:10   16:00:00       2
Parkes            64    -33.0         211.7        12:26:23   16:00:00     1,2

(1) Real time signal detection
(2) Nodding between Huygens and reference
(3) No nodding; continuous Huygens tracking


Supplementary Table 2   Radio Link Budget: Huygens-to-GBT

Transmitter Parameters
RF Power (dBm)                          40.7
Probe Antenna Gain (dBi)                 3.5
Losses (dB)                             -0.4
Effective Radiated Power (dBm)          43.8
Propagation Space Loss (dB)           -280.5
Receiving Antenna Gain (dBi)            65.0

Power Summary
Received Power (dBm)                  -171.7
Noise Spectral Density (dBm/Hz)       -183.8
Received Pt/N0  (dB Hz)                 12.1
Modulation Loss (dB)                    -4.5
Received Pc/N0 (dB Hz)                   7.6
Voltage SNR at tau = 1s                  3.4