Last update: January, 8th 2022
It may happen to run across STANAG-4481F transmissions which have a weird raster pattern which in turn is represented by the bit editor as a 3-bit period stream. This page collects those "catches" (see the table below) and tries to make sense of this unexpected behavior, explaining the reasons.
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Fig. 1
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Discussing the signal with my friend cryptomaster, we tend to think that a 50 bps data flow is transmitted using a device which is designed to transmit only with a speed of 75 bps. Indeed, the ratio 75/50 is equal to 1.5 thus each "original" bit is repeated 1.5 times. The bit editors work with an integer number of bits (they can't represent half bit) thus the 1.5 bit view is possible only by aggregating two consecutive frames and then getting an integer number of 3 consecutive bits (i.e. 1.5 x 2): thus the 3-bit structure that we see. Therefore the bits of the stream are actually allocated as follows:
Thus, after filtering out the column of the replicated bits it turns out the actual 50Bd speed. Resizing the new stream into a 7-bit pattern, the KW-46 sync sequence - generated by the polynomial x^31+x^3+1 - emerges (figure 2).
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Fig. 2
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For what concerns the speed of manipulation, a S-4481F transmission lasting for example 10 seconds generates 750 bits that can be arranged into a 3 x 250 bits pattern; by removing one column we get 2 x 250 = 500 bits that just match a 50 Baud transmission of the same duration (10 seconds).
In the light of the above, I analyzed again the signals in order to
verify what we hypothesized and found above. I compared a signal from
NSY Niscemi recorded on 6383 KHz (3-bit pattern S-4481F) and another one
from NAU Isabela 12120 KHz (plain S-4481F) by using the modified
quadrature amplitude detector of SA software: you can valuate the
different results (figure 3).
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| Fig.3 |
Even more interesting: all the signals from Niscemi show the extra
harmonics EXCEPT the signal on 6942 KHz which is correctly modulated
(figure 4) and coincidentally does not shows the strange 3-bit pattern .
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| Fig. 4 |
Then I selected the 50 Hz clock from the NSY signal and subsequently I
demodulate it by using the synch'ed FSK demodulator: the test was
successful and replicated the same results that I found using the theory
and manipulating the bitstreams (Figure 5). Thus,
50 Baud seems to be the
right working speed! As proved, decoding those signals using standards modes, or changing the
speeds to 50 bps, unfortunately does not work: the only successful way
is to sync the FSK demodulator to the 50 Hz clock of the signals.
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| Fig.5 | |
So, if the analysis is correct, it seems that they use the
75 bps STANAG-4481F waveform to send 50 bps streams(?!): usually in synchronous transmissions
the DTE provides the transmit clock to the modem but perhaps
they could use a modem - e.g. like the Harris RF-5710A - which can
recover the clock automatically from the incoming transmit data
(transmit clock set to "DATA" or in "recovery mode").
75Bd(50) STANAG-4481 heard transmissions:
| Freq. (cf) |
Tx Station |
| 5120.5 |
NSY |
| 5189.5 |
- |
| 5716.0 |
NAU |
| 6383.0 |
NSY |
| 6114.0 |
PLA |
| 6732.0 |
AJE |
| 7545.5 |
NSY |
| 8145.0 |
NSY |
| 8145.0 |
AJE |
| 8204.5 |
AJE |
| 8564.0 |
- |
| 9338.0 |
NAU |
| 11980.6 |
AJE |
| 13229.0 |
NAU |
| AJE | USAF, Barford St.John/Croughton UK |
| NAU | US Navy, Isabela PR |
| NPM | US Navy, Lualualei Hi |
| NSY | US Navy, NRTF Niscemi/Sigonella It |
| PLA | HFGCS, Lajes Field Azores |
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