mirror of
https://github.com/saitohirga/WSJT-X.git
synced 2024-11-16 09:01:59 -05:00
278 lines
13 KiB
Plaintext
278 lines
13 KiB
Plaintext
Possible FT8 Enhancements for Contesting
|
|
----------------------------------------
|
|
|
|
In addition to all the standard FT8 messages, FT8 DXpedition Mode
|
|
defines a new message type to convey messages like this example
|
|
acknowledging completion of a QSO with K1ABC and initiating a QSO with
|
|
W9XYZ:
|
|
|
|
K1ABC RR73; W9XYZ <KH1/KH7Z> -11
|
|
|
|
With 15s T/R sequencing and otherwise using standard FT8 messages,
|
|
this feature allows QSO rates up to 120/hour with one Tx signal. The
|
|
callsign enclosed in angle brackets is sent as a 10-bit hash code.
|
|
|
|
High QSO rates are also desirable for contest operating, but some
|
|
details are quite different from the DXpedition case. Contesting is a
|
|
many-to-many (as opposed to many-to-one) activity. We distinguish
|
|
between "Run stations" and "S+P stations" rather than between "Fox"
|
|
and "Hounds".
|
|
|
|
An optimal sequence of messages suitable for contesting looks
|
|
something like the list in Table 1, where {exch} represents the
|
|
required contest exchange. With 15 s transmissions and a steady
|
|
stream of callers, messages like these can support QSO rates
|
|
approaching 120/hour.
|
|
|
|
Table 1. Example sequence of FT8 contest messages
|
|
-------------------------------------------------------------------------
|
|
Run station S+P stations
|
|
-------------------------------------------------------------------------
|
|
1. CQ K1ABC
|
|
2. K1ABC W9XYZ, K1ABC G4AAA, ...
|
|
3. W9XYZ K1ABC {exch}
|
|
4. K1ABC W9XYZ {exch}
|
|
5. TU; G4AAA K1ABC {exch}
|
|
6. K1ABC G4AAA {exch}
|
|
7. TU; VE2BBB K1ABC {exch}
|
|
8. K1ABC VE2BBB {exch}
|
|
9. ...
|
|
-------------------------------------------------------------------------
|
|
|
|
In some circumstances one or both station callsigns may safely be
|
|
taken as known by context. High-rate contest transmissions in SSB,
|
|
CW, and RTTY can therefore be considerably shortened with no resulting
|
|
ambiguity for attentive operators. CQing stations need not include
|
|
their own callsign in every transmission, while S+P stations may send
|
|
only their own callsign at first, as in line 2 of Table 2, and then
|
|
only the contest exchange, as in line 4.
|
|
|
|
Table 2. Abbreviated contest messages
|
|
-------------------------------------------------------------------------
|
|
Run station S+P stations
|
|
-------------------------------------------------------------------------
|
|
1. CQ K1ABC
|
|
2. W9XYZ, G4AAA, ...
|
|
3. W9XYZ {exch}
|
|
4. {exch} (sent by W9XYZ)
|
|
5. TU; G4AAA {exch}
|
|
6. {exch} (sent by G4AAA)
|
|
7. TU; VE2BBB {exch}
|
|
8. {exch} (sent by VE2BBB)
|
|
9. TU; CQ K1ABC
|
|
10. ...
|
|
-------------------------------------------------------------------------
|
|
|
|
There would be no advantage to such message brevity with FT8. FT8
|
|
transmissions are of fixed duration, by design; and the AP decoder can
|
|
treat the home callsign and previously decoded callsigns as
|
|
hypothetically given, thereby making the effective code rate lower and
|
|
sensitivity up to 4 dB better.
|
|
|
|
Required exchange information for some relevant contests is
|
|
illustrated in Table 3, along with a breakdown of bit requirements for
|
|
each component of the exchange. Lower-case letter-number combinations
|
|
such as r1, r3, s7,... in the table suggest the meanings and indicate
|
|
the number of bits required to convey each part of the exchange.
|
|
Further details are given below the Table. Parameter T1 is the total
|
|
number of exchange bits, and T2=T1+56 is the number of bits for the
|
|
full message, including two standard 28-bit callsigns.
|
|
|
|
Table 3. Examples of required contest exchanges {exch}
|
|
------------------------------------------------------------------------------
|
|
Event Exchange Example Bits T1 T2
|
|
------------------------------------------------------------------------------
|
|
ARRL RTTY US/Can: rpt state/prov R 579 MA r1 r3 s7 11 67
|
|
DX: rpt serial R 559 0013 r1 r3 n12 16 72
|
|
|
|
Field Day US/Can: OpClass Section R 6A EMA r1 n5 c3 s7 16 72
|
|
DX: OpClass DX R 1A DX r1 n5 c3 s7 16 72
|
|
|
|
CQ WPX RTTY RST + serial R 589 0013 r1 r3 n12 16 72
|
|
|
|
CQ WW RTTY US/Can: RST CQZ state/prov R 579 8 NJ r1 r3 z6 s6 16 72
|
|
DX: RST + CQzone R 559 3 r1 r3 z6 10 66
|
|
|
|
ARRL VHF+ grid4 R FN42 r1 g15 16 72
|
|
|
|
EU VHF+ rpt serial grid6 R 590013 IO91NP r1 r3 n12 g25 41 97
|
|
------------------------------------------------------------------------------
|
|
Meaning and number of bits for each exchange component:
|
|
|
|
c3 Operating class (A-F)
|
|
g15 grid4
|
|
g25 grid6
|
|
n12 Serial number
|
|
n5 Number of transmitters (0-31)
|
|
r1 acknowledgment of received exchange
|
|
r3 3-bit report (0-7 ==> -24 to +18 dB, effectively "S2 to "S9")
|
|
s6 US state or Canadian province (48+14=62)
|
|
s7 ARRL/RAC Section (83 sections)
|
|
z6 CQ zone
|
|
------------------------------------------------------------------------------
|
|
|
|
How best to accommodate all these possibilities within the 72+3-bit
|
|
FT8 message payload? Let i3 (aka "i3bit") denote message type, with
|
|
available range 0-7. Type 0 is already used for standard JT-style
|
|
structured messages and free text, and type 1 for DXpedition mode.
|
|
Examples of suggested new message types 2 through 6 are summarized in
|
|
the Table 4.
|
|
|
|
Table 4. Proposed FT8 message types
|
|
------------------------------------------------------------------------------
|
|
i3 Example message Bits i72 Total Special purpose
|
|
------------------------------------------------------------------------------
|
|
0 K1ABC W9XYZ EN37 28 28 15 0 72 Standard message
|
|
0 FREE TEXT 71 1 72 Free text
|
|
1 K1ABC RR73; W9XYZ <KH1/KH7Z> -11 28 28 10 6 72 DXpedition Mode
|
|
2 W9XYZ K1ABC x16 28 28 16 72 Contesting
|
|
3 TU; G4AAA K1ABC x16 28 28 16 72 Contesting with "TU;"
|
|
4 <K1ABC> W9XYZ/R R x25 17 28 1 1 25 72 Rovers, Grid6
|
|
5 <K1ABC> PJ4/W9XYZ 17 49 66 Compound TxCall
|
|
6 PA9XYZ R 590003 IO91NP 28 1 3 12 24 68 EU VHF contest
|
|
7 tbd...
|
|
|
|
The first callsign in a message can also be "CQ" and a few other
|
|
special tokens. Type 3 messages are the same as type 2 except for
|
|
including "TU;", the completion-of-QSO indicator. Message fragments
|
|
x16 and x25 represent generic contest exchanges. A "contest template"
|
|
will define the specific source encoding/decoding needed for each
|
|
event.
|
|
|
|
Suggested message types 4 and 5 use a 17-bit hash for the first
|
|
callsign. I'm imagining that we'd start with a 32-bit crc and then
|
|
use its remainder after dividing by the prime number 131063. Values
|
|
less than 131063 will be the desired hash code, and the nine values
|
|
131063-131071 can be assigned special meanings such as CQ, QRZ, etc.
|
|
Type 4 messages identify the transmitting station as a Rover and can
|
|
also accommodate 6-digit grid locators. Type 5 messages allow the
|
|
transmitting station to send a full compound callsign with add-on
|
|
prefixes up to 4 characters and suffixes up to 3. Compound callsigns
|
|
are also permissible for the hashed callsigns in message types 4 and
|
|
5.
|
|
|
|
Contest Operating
|
|
-----------------
|
|
|
|
Operating in this proposed FT8 Contest Mode would be similar to that
|
|
in current RTTY contests. CQing stations will be distributed over 20
|
|
kHz or more on each band, perhaps at ~500 Hz separation. They will
|
|
respond to callers on their own frequency +/- ~200 Hz. Thus, a CQing
|
|
station and callers should occupy no more than 500 Hz total bandwidth.
|
|
CQers might always transmit at Tx audio frequency 1750 Hz and
|
|
configure their FT8 decoders to respond to signals between 1500 and
|
|
2000 Hz. S+P stations will typically work their way up or down the
|
|
band, perhaps in steps of 2 or 3 kHz, looking for unworked CQers. The
|
|
FT8 Contest GUI will offer special features for CQ mode and S+P mode
|
|
that make such conventions easy to follow.
|
|
|
|
Some Pertinent Questions
|
|
------------------------
|
|
|
|
1. FT8 is a good mode, but does it make for a good contesting mode?
|
|
|
|
The model described above maxes out at 120 QSOs/hour. (One can
|
|
imagine SO2R or even SO3R extensions, doubling or tripling that
|
|
limit.) Should we consider T/R sequences of 10s, or even 5s, to get
|
|
potentially higher rates? Should we consider giving up synchronized,
|
|
fixed-length sequences entirely, and use operator-determined start
|
|
times and transmission lengths? That's a significant departure from
|
|
all existing WSJT-X modes.
|
|
|
|
2. How much automation should be permissible?
|
|
|
|
We're not aiming to make a contesting robot. We want something that
|
|
rewards operator and station performance. The recently introduced FT8
|
|
DXpedition Mode offers the "Fox" operator a list of decoded "Hounds"
|
|
sorted by Call, Grid, S/N, Distance, or Random order. Hounds must
|
|
initiate their calls to Fox, and Fox must manually select each Hound
|
|
to be called. Otherwise, QSOs proceed with standard FT8
|
|
"auto-sequencing". Is this model acceptable?
|
|
|
|
3. How much bandwidth? How much sensitivity?
|
|
|
|
RTTY signals use bandwidth ~220 Hz and require S/N around -5 dB or
|
|
better, measured in a 2500 Hz bandwidth. FT8 uses signal bandwidth 50
|
|
Hz and reaches threshold sensitivity between -20 and -24 dB, depending
|
|
on how much a priori (AP) information is available. Shorter
|
|
transmissions conveying the same messages would increase the
|
|
bandwidth, S/N threshold, and potential QSO rate proportionally. Has
|
|
FT8 already hit the "sweet spot" of such trade-offs?
|
|
|
|
4. Suitable power limits?
|
|
|
|
WSJT-X modes are designed as weak-signal modes. They have strong FEC
|
|
and don't suffer from partial or corrupted copy. Sensitivity already
|
|
beats RTTY by 15-19 dB, so arguably it makes sense for an FT8 contest
|
|
or contest category to be limited to 100 W or even QRP power levels.
|
|
|
|
5. What software should provide the operator's GUI?
|
|
|
|
Things are described above as though WSJT-X, the software that
|
|
introduced FT8, would be used for contest operating. WSJT-X can send
|
|
QSO information to N1MM+ and other logging programs, so they could be
|
|
used in combination with WSJT-X. Alternatively, we could set things
|
|
up so that N1MM+ is the control program and FT8 encoding/decoding is
|
|
provided by a plug-in "MMFT8" similar to MMTTY. Operators already
|
|
into serious RTTY contesting would probably like the N1MM-in-control
|
|
option. However, existing FT8 users might be more comfortable with
|
|
WSJT-X in full control. Moreover, WSJT-X offers full support for
|
|
Linux and MacOS, which N1MM+ does not.
|
|
|
|
########################################################################
|
|
|
|
More thinking, beyond the above...
|
|
|
|
FT8 currently uses LDPC(174,87), where 87=72+3+12. Suggest going to
|
|
LDPC(174,91), with 91=72+5+14. This would give us 32 message types
|
|
rather than 7, and stronger suppression of false decodes. SNR penalty
|
|
would be 10log(91/87)=0.2 dB.
|
|
|
|
MSK144 currently uses LDPC(128,80), where 80=72+8. Suggest going to
|
|
LDPC(128,87), with 87=72+5+10. SNR penalty is 0.4 dB.
|
|
|
|
ARRL RTTY Roundup
|
|
-------------------------------------------------------------------------
|
|
Run station S+P stations
|
|
-------------------------------------------------------------------------
|
|
1. CQ K1ABC
|
|
2. K1ABC W9XYZ, K1ABC G4AAA, ...
|
|
3. W9XYZ K1ABC 579 MA
|
|
4. K1ABC W9XYZ 599 WI
|
|
5. TU; G4AAA K1ABC 559 MA
|
|
6. K1ABC G4AAA 579 0013
|
|
7. TU; VE2BBB K1ABC 599 MA
|
|
8. K1ABC VE2BBB 599 QC
|
|
9. TU; CQ K1ABC
|
|
-------------------------------------------------------------------------
|
|
|
|
|
|
NA VHF Contest
|
|
-------------------------------------------------------------------------
|
|
Run station S+P station i3
|
|
-------------------------------------------------------------------------
|
|
1. CQ K1ABC/R FN54 0
|
|
2. K1ABC W9XYZ EN37 0
|
|
3. W9XYZ K1ABC R FN54 2
|
|
4. K1ABC W9XYZ RR73 0
|
|
5. CQ K1ABC/R FN54 0
|
|
-------------------------------------------------------------------------
|
|
1. CQ K1ABC FN42 0
|
|
2. <K1ABC> W9XYZ/R EN47 5
|
|
3. W9XYZ K1ABC R FN42 0
|
|
4. DE W9XYZ/R RR73 0
|
|
5. CQ K1ABC FN42 0
|
|
-------------------------------------------------------------------------
|
|
|
|
|
|
|
|
EU VHF+ Contest
|
|
-------------------------------------------------------------------------
|
|
Run station S+P station i3
|
|
-------------------------------------------------------------------------
|
|
1. CQ G4ABC IO91 0
|
|
2. G4ABC PA9XYZ JO22 0
|
|
3. PA9XYZ 590003 IO91NP 6
|
|
4. G4ABC R 570007 JO22DB 6
|
|
5. PA9XYZ G4ABC RR73 0
|