7 September 2022

Harris wideband operations (a bit "intruding" within the 7 MHz HAM band)

Wideband activity was heard at the end of August around 7 MHz (figure 1) using mainly Romanian and Greek KiwiSDR receivers, my friend KarapuZ sent me his recordings which are of a much better quality than mine and therefore more suitable for analysis. According my friend, this network was set up around March-April 2022 and is well audible in our area since the network is presumably deployed in the south-east of Europe.

Fig. 1 - wideband transfers

Waveforms, durations and signal sequences in my opinion point to Harris devices: they have in fact developed and implemented  a wide band ALE (WBALE) adaptive system that selects the best channel, the available bandwidth and the frequency offset required for optimal wideband communications [1]. As I already mentioned in some blog posts, Harris WBALE relies on 3G-HF STANAG 4538 Fast Link Setup (FLSU) to establish a wideband link:

- the calling station first places a call using STANAG 4538 FLSU to exchange profiles of the two linking radios’ and and negotiate a traffic waveform
– the standard FLSU Request PDU has a traffic type parameter; Harris uses a new value of this parameter (reserved but not defined in  STANAG 4538: see table 4.6.1-2 "second 6-bit argument field") to indicate that a wideband link is to be established
- the radios then use an additional handshake (not defined in STANAG 4538) to negotiate bandwidth and offset (from the assigned frequency, see figure 1) to be used, based on the results of the preceeding "spectrum sensing"  (1).

Figure 2 shows the timing diagram of all the signalling required for the Harris WBALE protocol: the timing diagram follows the one described in 188-141D App.G, even if the used waveforms are different!

Fig. 2 - wideband session timing and real-world wideband transfer
 

Traffic is exchanged using Harris proprietary WHARQ waveforms family, quite well recognizable by their "superframe" consisting of a STANAG-4538 BW6 preamble followed by 8 frames each characterized by a different miniprobe pattern.  An ACK PDU is transmitted by the receive station using a BW6 burst waveform. Figure 3 shows the main parameters of the WHARQ 2400 Bd 3-KHz bandwidth waveform.

Fig. 3 - WHARQ 2400 Bd 3-KHz bandwidth waveform

As I titled, the problem lies in the fact that one of the WB channels occupies about 12 kHz of the low part of the 7 HAM MHz band. It must be said that the 7 MHz band is primarily assigned to radio amateurs, however also shortwave broadcasters and land mobile users have primary allocations in some countries so amateur stations must share bandwidth with these users. 

The choice of the 7 MHz for such milcomms is probably related to the "primary and secondary users" concept [3] which divides the users into primary users (licensed) and secondary users (unlicensed): the first “own” the bandwidth allocation while secondary users are only allowed to use this spectrum in a non-interfering basis:

a) for WBALE primary user mode, stations that link for the purpose of transferring data will use a bandwidth and offset in each direction that is chosen to maximize the signal-to-noise ratio (SNR) with which transmissions in each direction are received. Stations will avoid interference with other stations within the same network, but will make no effort to prevent interference with other stations outside the network, except as a byproduct of optimizing communications within the network.  This can have at least two significant implications:
1. the bandwidth and offset used in each direction of the link may be different;
2. the stations may cause harmful interference to communications in other networks while themselves not experiencing harmful interference. 

b) in secondary user mode, WBALE stations will not (as far as is practical) cause interference to other stations outside the network that are operating within the same channel allocations used by the network. In particular, whenever a link is established for a wideband data transfer, the bandwidth and offset used for the link will be chosen so as to avoid interference with any transmission detected by either side. This is likely to require that the same bandwidth and offset be used in both link directions.  

As you may see in figure 1, the bandwidth and offset used in each direction of each logical link are the same, threfore, in my opinion, it seems that they use this portion of band (7 MHz) in secondary user mode.

Fig. 4 - a Rockwell Collins modem performing the spectrum sensing (2)

(1) To effectively utilize the allocated bandwidth, WBALE will need to listen to an entire wideband channel of up to 24 kHz, detect the presence of interfering signals on the channel that could render all or part of the channel unusable, and identify any portion of the channel that may still be usable even if the channel is partly blocked. This function is referred to as "spectrum sensing".

2) Initial Wideband ALE developing and testing was condected togheter by Harris and Rockwel Collins.
 
 
[3] William N. Furman, John W. Nieto, Eric N. Koski: The 10th Nordic Conference on HF (2013)
 

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