First cut at replacing QRA64 with Q65 throughout the User Guide.

doc/common/license.adoc

@@ -27,9 +27,10 @@ our work under terms of the GNU General Public License must display
 the following copyright notice prominently:
 
 *The algorithms, source code, look-and-feel of _{prog}_ and related
-programs, and protocol specifications for the modes FSK441, FT4, FT8,
-JT4, JT6M, JT9, JT65, JTMS, QRA64, ISCAT, and MSK144 are Copyright (C)
-2001-2020 by one or more of the following authors: Joseph Taylor,
-K1JT; Bill Somerville, G4WJS; Steven Franke, K9AN; Nico Palermo,
-IV3NWV; Greg Beam, KI7MT; Michael Black, W9MDB; Edson Pereira, PY2SDR;
-Philip Karn, KA9Q; and other members of the WSJT Development Group.*
+programs, and protocol specifications for the modes FSK441, FST4,
+FST4W, FT4, FT8, JT4, JT6M, JT9, JT44, JT65, JTMS, Q65, QRA64, ISCAT,
+and MSK144 are Copyright (C) 2001-2021 by one or more of the following
+authors: Joseph Taylor, K1JT; Bill Somerville, G4WJS; Steven Franke,
+K9AN; Nico Palermo, IV3NWV; Greg Beam, KI7MT; Michael Black, W9MDB;
+Edson Pereira, PY2SDR; Philip Karn, KA9Q; and other members of the
+WSJT Development Group.*

doc/user_guide/en/controls-functions-center.adoc

@@ -60,7 +60,7 @@ specified response frequency.
 * Checkboxes at bottom center of the main window control special
 features for particular operating modes:
 
-** *Sh* enables shorthand messages in JT4, JT65, QRA64 and MSK144 modes
+** *Sh* enables shorthand messages in JT4, JT65, Q65, and MSK144 modes
 
 ** *Fast* enables fast JT9 submodes
 
@@ -69,4 +69,5 @@ features for particular operating modes:
 ** *Call 1st* enables automatic response to the first decoded
 responder to your CQ
 
-** *Tx6* toggles between two types of shorthand messages in JT4 mode
+** *Tx6* toggles between two types of shorthand messages in JT4 and
+    Q65 modes

doc/user_guide/en/decoder_notes.adoc

@@ -2,12 +2,12 @@
 
 === AP Decoding
 
-The _WSJT-X_ decoders for FST4, FT4, FT8, JT65, and QRA64 include 
+The _WSJT-X_ decoders for FST4, FT4, FT8, JT65, and Q65 include
 procedures that use naturally accumulating information during a
 minimal QSO.  This _a priori_ (AP) information increases sensitivity
 of the decoder by up to 4 dB, at the cost of a slightly higher rate of
-false decodes.  AP is optional in FT8, JT65, and QRA64, but is always
-enabled for FT4 and FST4 when decode depth is Normal or Deep.
+false decodes.  AP is optional in FT8 and JT65, but is always enabled
+for Q65 and for FT4 and FST4 when decode depth is Normal or Deep.
 
 For example: when you decide to answer a CQ, you already know your own
 callsign and that of your potential QSO partner.  The software
@@ -132,25 +132,16 @@ End of line information::
  `d` - Deep Search algorithm +
  `f` - Franke-Taylor or Fano algorithm +
  `N` - Number of Rx intervals or frames averaged +
- `P` - Number indicating type of AP information (Table 1, above) +
+ `P` - Number indicating type of AP information (Table 1 or Table 6) +
 
-Table 6 below shows the meaning of the return codes R in QRA64 mode.
-
-[[QRA64_AP_INFO_TABLE]]
-.QRA64 AP return codes
-[width="35%",cols="h10,<m20",frame=topbot,options="header"]
+[[Q65_AP_INFO_TABLE]]
+.Q65 end-of-line codes
+[width="45%",cols="h10,<m20",frame=topbot,options="header"]
 |===============================================
-|rc | Message components
-|0  | ?    &#160; &#160;   ?   &#160; &#160;   ?
-|1  | CQ   &#160; &#160;   ?   &#160; &#160;   ? 
-|2  | CQ   &#160; &#160;   ?   
-|3  | MyCall   &#160; &#160;   ?   &#160; &#160;   ? 
-|4  | MyCall   &#160; &#160;   ?  
-|5  | MyCall DxCall &#160; &#160;   ?
-|6  | ?    &#160; &#160;   DxCall   &#160; &#160;   ?
-|7  | ?    &#160; &#160;   DxCall   
-|8  | MyCall     DxCall DxGrid
-|9  | CQ     DxCall &#160; &#160;   ?
-|10 | CQ     DxCall 
-|11 | CQ     DxCall DxGrid
+|   | Message components
+|q0  | ?    &#160; &#160;   ?   &#160; &#160;   ?
+|q1  | CQ   &#160; &#160;   ?   &#160; &#160;   ? 
+|q2  | MyCall   &#160; &#160;   ?   &#160; &#160;   ? 
+|q3  | MyCall DxCall &#160; &#160;   ?
+|q4  | MyCall DxCall &#160; &#160; [<blank> \| RRR \| RR73 \| 73]
 |===============================================

doc/user_guide/en/introduction.adoc

@@ -15,7 +15,7 @@ first seven are designed for making reliable QSOs under weak-signal
 conditions. They use nearly identical message structure and source
 encoding.  JT65 was designed for EME ("`moonbounce`") on VHF and
 higher bands and is mostly used for that purpose today.  Q65 replaces
-an earlier mode, QRA64; it is particularly effective for tropospheric
+an earlier mode, QRA64.  Q65 is particularly effective for tropospheric
 scatter, rain scatter, ionospheric scatter, TEP, and EME on VHF and
 higher bands, as well as other types of fast-fading signals.  JT9 was
 originally designed for the HF and lower bands.  Its submode JT9A is 1

doc/user_guide/en/protocols.adoc

@@ -169,25 +169,25 @@ same as that of the sync tone used in long messages, and the frequency
 separation is 110250/4096 = 26.92 Hz multiplied by n for JT65A, with n
 = 2, 3, 4 used to convey the messages RO, RRR, and 73, respectively.
 
-[[QRA64_PROTOCOL]]
-==== QRA64
+[[Q65_PROTOCOL]]
+==== Q65
 
-QRA64 is intended for EME and other extreme weak-signal applications.
-Its internal code was designed by IV3NWV.  The protocol uses a (63,12)
-**Q**-ary **R**epeat **A**ccumulate code that is inherently better
-than the Reed Solomon (63,12) code used in JT65, yielding a 1.3 dB
-advantage. A new synchronizing scheme is based on three 7 x 7 Costas
-arrays.  This change yields another 1.9 dB advantage.
+Q65 is intended for scatter, EME, and other extreme weak-signal
+applications.  Forward error correction (FEC) uses a specially
+designed (65,15) block code with six-bit symbols.  Two symbols are
+“punctured” from the code, yielding an effective (63,13) code with a
+payload of k = 13 information symbols conveyed by n = 63 channel
+symbols.  The punctured symbols consist of a 12-bit CRC computed from
+the 13 information symbols.  The CRC is used to reduce the
+false-decode rate to a very low value.  A 22-symbol pseudo-random
+sequence spread throughout a transmission is sent as “tone 0” and used
+for synchronization.  The total number of channel symbols in a Q65
+transmission is thus 63 + 22 = 85.
 
-In most respects the current implementation of QRA64 is operationally
-similar to JT65.  QRA64 does not use two-tone shorthand messages, and
-it makes no use of a callsign database.  Rather, additional
-sensitivity is gained by making use of already known information as a
-QSO progresses -- for example, when reports are being exchanged and
-you have already decoded both callsigns in a previous transmission.
-QRA64 presently offers no message averaging capability, though that
-feature may be added.  In early tests, many EME QSOs were made using
-submodes QRA64A-E on bands from 144 MHz to 24 GHz.  
+For each T/R sequence length, submodes A - E have tone spacings and
+occupied bandwidths 1, 2, 4, 8, and 16 times those specified in the
+above table.  Full submode designations include a number for sequence
+length and a letter for tone spacing, as in Q65-15A, Q65-120C, etc.
 
 [[WSPR_PROTOCOL]]
 ==== WSPR
@@ -277,8 +277,12 @@ which the probability of decoding is 50% or higher.
 |FT8  |LDPC |(174,91)| 8| 8-GFSK| 6.25 | 50.0 | 0.27| 12.6 | -21
 |JT4A |K=32, r=1/2|(206,72)| 2| 4-FSK| 4.375| 17.5 | 0.50| 47.1 | -23
 |JT9A |K=32, r=1/2|(206,72)| 8| 9-FSK| 1.736| 15.6 | 0.19| 49.0 | -26
-|JT65A |Reed Solomon|(63,12) |64|65-FSK| 2.692| 177.6 | 0.50| 46.8 | -25
-|QRA64A|Q-ary Repeat Accumulate|(63,12) |64|64-FSK|1.736|111.1|0.25|48.4| -26
+|JT65A |RS|(63,12) |64|65-FSK| 2.692| 177.6 | 0.50| 46.8 | -25
+|Q65-15A |QRA|(63,13) |64|65-FSK|6.667|433|0.26| 12.8| -22.2
+|Q65-30A |QRA|(63,13) |64|65-FSK|3.333|217|0.26| 25.5| -24.8
+|Q65-60A |QRA|(63,13) |64|65-FSK|1.667|108|0.26| 51.0| -27.6
+|Q65-120A|QRA|(63,13) |64|65-FSK|0.750| 49|0.26|113.3| -30.8
+|Q65-300A|QRA|(63,13) |64|65-FSK|0.289| 19|0.26|293.8| -33.8
 | WSPR |K=32, r=1/2|(162,50)| 2| 4-FSK| 1.465| 5.9 | 0.50|110.6 | -31
 |FST4W-120  |LDPC |  (240,74)| 4| 4-GFSK|  1.46  |  5.9  | 0.25| 109.3 | -32.8
 |FST4W-300  |LDPC |  (240,74)| 4| 4-GFSK|  0.558  |  2.2  | 0.25| 286.7 | -36.8
@@ -286,14 +290,18 @@ which the probability of decoding is 50% or higher.
 |FST4W-1800 |LDPC |  (240,74)| 4| 4-GFSK|  0.089 |  0.36 | 0.25| 1792.0| -44.8
 |===============================================================================
 
-Submodes of JT4, JT9, JT65, and QRA64 offer wider tone spacings for
+ LDPC = Low Density Parity Check
+ RS = Reed Solomon
+ QRA = Q-ary Repeat Accumulate
+
+Submodes of JT4, JT9, and JT65 offer wider tone spacings for
 circumstances that may require them, such as significant Doppler spread.
 Table 8 summarizes the tone spacings, bandwidths, and approximate
 threshold sensitivities of the various submodes when spreading is
 comparable to tone spacing.
 
 [[SLOW_SUBMODES]]
-.Parameters of Slow Submodes with Selectable Tone Spacings
+.Parameters of Slow Submodes JT4, JT9, and JT65 with Selectable Tone Spacings
 [width="50%",cols="h,3*^",frame=topbot,options="header"]
 |=====================================
 |Mode  |Tone Spacing  |BW (Hz)|S/N (dB)
@@ -315,11 +323,17 @@ comparable to tone spacing.
 |JT65A |2.692| 177.6  |-25
 |JT65B |5.383| 352.6  |-25
 |JT65C |10.767| 702.5 |-25
-|QRA64A|1.736| 111.1  |-26
-|QRA64B|3.472| 220.5  |-25
-|QRA64C|6.944| 439.2  |-24
-|QRA64D|13.889| 876.7 |-23
-|QRA64E|27.778|1751.7 |-22
+|=====================================
+
+.Parameters of Q65 Submodes
+[width="100%",cols="h,5*^",frame=topbot,options="header"]
+|=====================================
+|T/R Period (s)  |A Spacing Width (Hz)|B Spacing Width (Hz)|C Spacing Width (Hz)|D Spacing Width (Hz)|E Spacing Width (Hz)
+|15|6.67     4.33|13.33     867|26.67     1733|N/A|N/A
+|30|3.33     217|6.67     433|13.33     867| 26.67     1733| N/A
+|60|1.67     108|3.33     217|6.67     433|13.33     867|26.67     1733
+|120|0.75     49|1.50     98|3.00     195|6.00     390| 12.00     780
+|300|0.29     19|0.58     38|1.16     75|2.31     150|4.63     301
 |=====================================
 
 [[FAST_MODES]]

doc/user_guide/en/utilities.adoc

@@ -89,25 +89,6 @@ You will discover that every possible JT65 message differs from every
 other possible JT65 message in at least 52 of the 63
 information-carrying channel symbols.
 
-Here's an example using the QRA64 mode:
-
- C:\WSJTX\bin qra64code "KA1ABC WB9XYZ EN37"
-      Message                 Decoded                Err? Type
- --------------------------------------------------------------------------
-   1 KA1ABC WB9XYZ EN37      KA1ABC WB9XYZ EN37          1:    Std Msg
-
- Packed message, 6-bit symbols  34 16 49 32 51 26 31 40 41 22  0 41
-
- Information-carrying channel symbols
-   34 16 49 32 51 26 31 40 41 22  0 41 16 46 14 24 58 45 22 45 38 54  7 23  2 49 32 50 20 33
-   55 51  7 31 31 46 41 25 55 14 62 33 29 24  2 49  4 38 15 21  1 41 56 56 16 44 17 30 46 36
-   23 23 41
-
- Channel symbols including sync
-   20 50 60  0 40 10 30 34 16 49 32 51 26 31 40 41 22  0 41 16 46 14 24 58 45 22 45 38 54  7
-   23  2 49 32 50 20 33 55 51 20 50 60  0 40 10 30  7 31 31 46 41 25 55 14 62 33 29 24  2 49
-    4 38 15 21  1 41 56 56 16 44 17 30 46 36 23 23 41 20 50 60  0 40 10 30
-
 Execution of any of these utility programs with "-t" as the only
 command-line argument produces examples of all supported message
 types.  For example, using `jt65code -t`:

doc/user_guide/en/vhf-features.adoc

@@ -11,13 +11,11 @@ higher bands.  These features include:
 
 - *JT65*, widely used for EME on VHF and higher bands
 
-- *Q65*, for propagation modes including tropospheric scatter, rain
-scatter, ionospheric scatter, TEP, and EME
+- *Q65*, for ionospheric scatter, tropospheric scatter, rain scatter, 
+TEP, and EME
 
 - *MSK144*, for meteor scatter
 
-- *ISCAT*, for aircraft scatter and other types of scatter propagation
-
 - *Echo* mode, for detecting and measuring your own lunar echoes
 
 - *Doppler tracking*, which becomes increasingly important for EME
@@ -177,49 +175,31 @@ image::JT65B.png[align="center",alt="JT65B"]
 
 === Q65
 
-Q65 is designed for propagation paths that produce signals exhibiting fast
-fading, including tropospheric scatter, rain scatter, ionospheric scatter,
-trans-equatorial propagation (TEP), and EME.  
+Q65 is designed for propagation paths that produce fast fading
+signals: tropospheric scatter, rain scatter, ionospheric scatter,
+trans-equatorial propagation (TEP), EME, and the like.  The following
+screen shot shows an example with submode Q65-30A on a 6-meter
+ionospheric scatter path of about 1100 km.
 
-EME on VHF and higher bands; its
-operation is generally similar to JT4 and JT65.  The following screen
-shot shows an example of a QRA64C transmission from DL7YC recorded at
-G3WDG over the EME path at 24 GHz.  Doppler spread on the path was 78
-Hz, so although the signal is reasonably strong its tones are
-broadened enough to make them hard to see on the waterfall.  The
-triangular red marker below the frequency scale shows that the decoder
-has achieved synchronization with a signal at approximately 967 Hz.
+image::Q65_6m_ionoscatter.png[align="center",alt="Q65"]
 
-image::Q65_6m_ionoscatter.png[align="center",alt="QRA64"]
-
-The QRA64 decoder makes no use of a callsign database.  Instead, it
+The Q65 decoder makes no use of a callsign database.  Instead, it
 takes advantage of _a priori_ (AP) information such as one's own
-callsign and the encoded form of message word `CQ`.  In normal usage,
-as a QSO progresses the available AP information increases to include
-the callsign of the station being worked and perhaps also his/her
-4-digit grid locator.  The decoder always begins by attempting to
-decode the full message using no AP information.  If this attempt
-fails, additional attempts are made using available AP information to
-provide initial hypotheses about the message content.  At the end of
-each iteration the decoder computes the extrinsic probability of the
-most likely value for each of the message's 12 six-bit information
-symbols.  A decode is declared only when the total probability for all
-12 symbols has converged to an unambiguous value very close to 1.
+callsign and the message word `CQ`.  In normal usage, as a QSO
+progresses the available AP information increases to include the
+callsign of the station being worked and perhaps also his/her 4-digit
+grid locator.  The decoder takes advantage of whatever AP information
+is available.  
 
-For EME QSOs some operators use short-form QRA64 messages consisting
-of a single tone.  To activate automatic generation of these messages,
-check the box labeled *Sh*.  This also enables the generation of a
-single tone at 1000Hz by selecting Tx6, to assist in finding  signals
-initially, as the QRA64 tones are often not visible on the waterfall.
-The box labeled *Tx6* switches the Tx6 message from 1000Hz to 1250Hz
-to indicate to the other station that you are ready to receive messages.
+For Q65 EME QSOs, particularly on the micriowave bands, some operators
+use short-form messages consisting of a single tone.  To activate
+automatic generation of these messages, check the box labeled *Sh*.
+This also enables the generation of a single tone at 1000Hz by
+selecting Tx6, to assist in finding signals initially.  The box
+labeled *Tx6* switches the Tx6 message from 1000Hz to 1250Hz to
+indicate to the other station that you are ready to receive messages.
 
-TIP: QRA64 attempts to find and decode only a single signal in the
-receiver passband.  If many signals are present, you may be able to
-decode them by double-clicking on the lowest tone of each one in the
-waterfall.
-
-TIP: G3WDG has prepared a more detailed tutorial on using {QRA64_EME}. 
+// TIP: G3WDG has prepared a more detailed tutorial on using {QRA64_EME}. 
 
 === MSK144
 
@@ -332,21 +312,28 @@ image::echo_144.png[align="center",alt="Echo 144 MHz"]
 
 === Tips for EME
 
-Current conventions dictate that digital EME is usually done with
-JT65A on the 50 MHz band, JT65B on 144 and 432 MHz, and JT65C on 1296
-MHz.  On higher microwave bands typical choices are JT65C or one of
+Until the advent of Q65, digital EME has mostly been done using JT65A
+on the 50 MHz band, JT65B on 144 and 432 MHz, and JT65C on 1296 MHz.
+On higher microwave bands typical choices have been JT65C or one of
 the wider QRA64 or JT4 submodes, depending on the expected amount of
-Doppler spread.  JT4 and JT65 offer message *Averaging* -- the
-summation of subsequent transmissions that convey the same message --
-to enable decodes at signal-to-noise ratios several dB below the
-threshold for single transmissions.  These modes also allow *Deep
-Search* decoding, in which the decoder hypothesizes messages
-containing known or previously decoded callsigns and tests them for
-reliability using a correlation algorithm.  Finally, JT65 and QRA64
-offer _a priori_ (AP) decoding, which takes advantage of naturally
-accumulating information during a QSO.  The following tutorial aims to
-familiarize you with these program features, all of which are of
-special interest for EME and other extreme weak-signal conditions.
+Doppler spread.  We now recommend a suitable submodes of Q65 for EME
+on all bands: for example, Q65-60A on 50 and 144 MHz, -60B on
+432 MHz, -60C on 1296 MHz, and -60D on 10 GHz.
+
+JT4, JT65, and Q65 offer *Message Averaging* -- the summation of
+subsequent transmissions that convey the same message -- to enable
+decodes at signal-to-noise ratios several dB below the threshold for
+single transmissions.  JT4 and JT65 also allow *Deep Search* decoding,
+in which the decoder hypothesizes messages containing known or
+previously decoded callsigns and tests them for reliability using a
+correlation algorithm.  JT65 and Q65 offer _a priori_ (AP)
+decoding, which takes advantage of naturally accumulating information
+during a QSO.
+
+////
+The following tutorial aims to familiarize you with
+these program features, all of which are of special interest for EME
+and other extreme weak-signal conditions.
 
 As a starting point, configure _WSJT-X_ as follows:
 
@@ -434,3 +421,5 @@ You might wish to experiment with other combinations of entries for
 options of the *Decode* menu on and off.  For best sensitivity, most
 users will want to use *Deep* decoding with  *Enable averaging*, 
 *Enable deep search*, and *Enable AP* all turned on.
+
+////