Many more edits of the User Guide.

git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6105 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2024-11-22 04:11:16 -05:00 · 2015-11-16 20:13:47 +00:00 · 2015-11-16 20:13:47 +00:00 · c3ded3d418
commit c3ded3d418
parent ab8098263a
35 changed files with 298 additions and 272 deletions
--- a/doc/CMakeLists.txt
+++ b/doc/CMakeLists.txt
@ -15,18 +15,16 @@ set (UG_SRCS
  user_guide/controls-functions-messages.adoc
  user_guide/controls-functions-status-bar.adoc
  user_guide/controls-functions-wide-graph.adoc
  user_guide/coop-prgrms.adoc
  user_guide/cooperating-programs.adoc
  user_guide/faq.adoc
  user_guide/font-sizes.adoc
  user_guide/implementation.adoc
  user_guide/install-from-source.adoc
  user_guide/install-linux.adoc
  user_guide/install-mac.adoc
  user_guide/install-windows.adoc
  user_guide/introduction.adoc
-  user_guide/jt65-jt9-differences.adoc
+  user_guide/protocols.adoc
  user_guide/jt65-protocol.adoc
  user_guide/jt9-protocol.adoc
  user_guide/logging.adoc
  user_guide/make-qso.adoc
  user_guide/new_features.adoc
@ -45,7 +43,6 @@ set (UG_SRCS
  user_guide/tutorial-example2.adoc
  user_guide/tutorial-main-window.adoc
  user_guide/tutorial-wide-graph-settings.adoc
  user_guide/tx-rx.adoc
  user_guide/utilities.adoc
  user_guide/vhf-features.adoc
  user_guide/wsjtx-main.adoc
--- a/doc/common/license.adoc
+++ b/doc/common/license.adoc
@ -12,4 +12,4 @@ GNU General Public License for more details.
 You should have received a copy of the GNU General Public License
 along with this documentation. If not, see {gnu_gpl}.
-Copyright (C) 2001-2015 Joseph H Taylor, Jr, {joe_taylor}.
+Copyright (C) 2001-2015 Joseph H Taylor, Jr., K1JT.
--- a/doc/common/links.adoc
+++ b/doc/common/links.adoc
@ -33,6 +33,7 @@ d). Edit lines as needed. Keeping them in alphabetic order help see dupes.
 // General URL's
 //:launchpadac6sl: https://launchpad.net/~jnogatch/+archive/wsjtx[WSJT-X Linux Packages]
 :alarmejt: http://f5jmh.free.fr/index.php?page=english[AlarmeJT]
 :asciidoc_cheatsheet: http://powerman.name/doc/asciidoc[AsciiDoc Cheatsheet]
 :asciidoc_help: http://www.methods.co.nz/asciidoc/userguide.html[AsciiDoc User Guide]
 :asciidoc_questions: http://www.methods.co.nz/asciidoc/faq.html[AsciiDoc FAQ]
@ -46,7 +47,7 @@ d). Edit lines as needed. Keeping them in alphabetic order help see dupes.
 :dev_guide: http://www.physics.princeton.edu/pulsar/K1JT/wsjtx-doc/wsjt-dev-guide.html[Dev-Guide]
 :devsvn1: http://sourceforge.net/p/wsjt/wsjt/HEAD/tree/[Devel-SVN]
 :devsvn: http://sourceforge.net/p/wsjt/wsjt/HEAD/tree/[SourceForge]
-:dimension4: http://www.thinkman.com/dimension4/[Dimension4]
+:dimension4: http://www.thinkman.com/dimension4/[Thinking Man Software]
 :download: http://physics.princeton.edu/pulsar/K1JT/wsjtx.html[Download Page]
 :dxatlas: http://www.dxatlas.com/[Afreet Software, Inc.]
 :dxlcommander: http://www.dxlabsuite.com/commander/[Commander]
@ -60,9 +61,9 @@ d). Edit lines as needed. Keeping them in alphabetic order help see dupes.
 :gnu_gpl: http://www.gnu.org/licenses/gpl-3.0.txt[GNU General Public License]
 :homepage: http://physics.princeton.edu/pulsar/K1JT/[WSJT Home Page]
 :hrd: http://www.hrdsoftwarellc.com/[Ham Radio Deluxe]
-:jt4eme: http://physics.princeton.edu/pulsar/K1JT/WSJT-X_for_JT4_v6.pdf[here]
+:jt4eme: http://physics.princeton.edu/pulsar/K1JT/WSJT-X_1.6.0_for_JT4_v7.pdf[here]
 :jt65protocol: http://physics.princeton.edu/pulsar/K1JT/JT65.pdf[QEX]
-:jtalert: http://hamapps.com[JT-ALERT-X]
+:jtalert: http://hamapps.hamspots.net[JT-ALERT-X]
 :kvasd-installer: http://physics.princeton.edu/pulsar/K1JT/kv-installer.txt[here]
 :launchpadki7mt: https://launchpad.net/~ki7mt[KI7MT PPA's]
 :log4om: http://www.log4om.com[Log4OM]
--- a/doc/user_guide/controls-functions-center.adoc
+++ b/doc/user_guide/controls-functions-center.adoc
@ -16,14 +16,14 @@ double-clicking on decoded text or a signal in the waterfall.  They
 can also be adjusted with spinner controls. 
 * You can force Tx frequency to the current Rx frequency by clicking
-the *Tx<Rx* button, and vice-versa for *Rx<Tx*.  (Copy is from right
+the *Tx<Rx* button, and vice-versa for *Rx<Tx*.  Check the box *Lock
-to left.)  Check the box *Lock Tx=Rx* to make the frequencies always
+Tx=Rx* to make the frequencies always track one another.  The
-track one another.  The on-the-air frequency of your lowest JT9 or
+on-the-air frequency of your lowest JT9 or JT65 tone is the sum of
-JT65 tone is the sum of dial frequency and audio Tx frequency.
+dial frequency and audio Tx frequency.
 IMPORTANT: In general we do not recommend using *Lock Tx=Rx* since it
 encourages poor radio etiquette when running a frequency.  With *Lock
-Tx=Rx* checked, your own frequency will move around following your
+Tx=Rx* checked, your own Tx frequency will move around following your
 callers.
 * The *Report* control lets you change a signal report that has been
--- a/doc/user_guide/controls-functions-left.adoc
+++ b/doc/user_guide/controls-functions-left.adoc
@ -19,16 +19,16 @@ format works only if a working frequency has been set up on that band,
 in which case the first working frequency on that band is
 selected. 
-* If you are using CAT control, a small colored square appears in
+* If you are using CAT control, a small colored circle appears in
 green if the CAT control is activated and functional.  The green
-square contains the character S if the rig is detected to be in
+circle contains the character S if the rig is detected to be in
-*Split* mode.  The square becomes red if you have requested CAT
+*Split* mode.  The circle becomes red if you have requested CAT
 control but communication with the radio has been lost.
 IMPORTANT: Many Icom rigs cannot be queried for split status, current
 VFO or split transmit frequency.  Consequently you should not change
 the current VFO, split status or frequency using controls on the radio
-when using _WSJT-X_.
+when using _WSJT-X_ with an Icom radio.
 * If *DX Grid* contains a valid Maidenhead locator, the corresponding
 great-circle azimuth and distance from your location are displayed.
--- a/doc/user_guide/controls-functions-main-window.adoc
+++ b/doc/user_guide/controls-functions-main-window.adoc
@ -9,8 +9,8 @@ image::images/main-ui-controls.png[align="left",width=650,alt="Main UI Controls"
 about a QSO you have nearly completed.  You can edit or add to this
 information before clicking *OK* to log the QSO.  If you check *Prompt
 me to log QSO* on the *Setup* menu, the program will raise the
-confirmation screen automatically when you send a 73 or free-text
+confirmation screen automatically when you send a message containing
-message.
+73.
 //.Log QSO Window
 image::images/log-qso.png[align="center",alt="Log QSO"]
@ -30,7 +30,7 @@ return to the original frequency.
 Double-clicking *Erase* clears both text windows.
 * *Decode* tells the program to repeat the decoding procedure at the
-Rx frequency (green marker on waterfall), using the most recently
+Rx frequency (green marker on waterfall scale), using the most recently
 completed sequence of received data.  
 * *Enable Tx* toggles the program into automatic T/R sequencing mode
@ -43,9 +43,9 @@ s into a UTC minute.
 automatic T/R sequencing.
 * *Tune* may be used to switch into Tx mode and generate an
-unmodulated carrier at the specified Tx frequency (red marker
+unmodulated carrier at the specified Tx frequency (red marker on
-on waterfall).  This process may be useful for adjusting an antenna
+waterfall scale).  This process may be useful for adjusting an antenna
-tuner.  The button is highlighted in red while *Tune* is
+tuner.  The button is highlighted in red while *Tune* is active.
-active.  Toggle the button a second time to terminate the *Tune*
+Toggle the button a second time or click *Halt Tx* to terminate the
-process.
+*Tune* process.
--- a/doc/user_guide/controls-functions-menus.adoc
+++ b/doc/user_guide/controls-functions-menus.adoc
@ -41,6 +41,8 @@ decoded message.
 ==== Help Menu
 image::images/help-menu.png[align="left",alt="Help Menu"]
 ===== Keyboard Shortcuts (F3)
 image::images/keyboard-shortcuts.png[align="left",alt="Help Menu"]
 ===== Special Mouse Commands (F5)
 image::images/special-mouse-commands.png[align="left",alt="Help Menu"]
--- a/doc/user_guide/controls-functions-messages.adoc
+++ b/doc/user_guide/controls-functions-messages.adoc
@ -21,7 +21,7 @@ a transmission.
 * All six Tx message fields are editable.  You can modify an
 automatically generated message or enter a desired message, keeping in
-mind the strict limits on message content.  See <<PROTOCOLS,Protocol
+mind the limits on message content.  See <<PROTOCOLS,Protocol
 Specifications>> for details.
 * Click on the pull-down arrow for message #5 to select one of the
--- a/doc/user_guide/controls-functions-wide-graph.adoc
+++ b/doc/user_guide/controls-functions-wide-graph.adoc
@ -24,11 +24,6 @@ updating the spectral display.  Values around 5 are suitable for
 normal JT9 and JT65 operation.  Adjust *N Avg* to make the waterfall
 move faster or slower, as desired.
 - *Zero* and *Gain* control the reference level and scaling for
 waterfall colors.  Values around 0 for both parameters are usually
 about right, depending on the input signal level, the chosen palette,
 and your own preferences.
 - A dropdown list below the *Palette* label lets you select from a
 wide range of waterfall color palettes.  
@ -37,13 +32,25 @@ user-defined palette.
 - Check *Flatten* if you want _WSJT-X_ to compensate for a sloping or
 uneven response across the received passband.  For this feature to
-work properly, remember to restrict the range of displayed frequencies
+work properly, you should restrict the range of displayed frequencies
 so that only the active part of the spectrum is shown.
 - Select *Current* or *Cumulative* for the spectrum displayed in the
 bottom one-third of the Wide Graph window.  *Current* is the average
 spectrum over the most recent *N Avg* FFT calculations.  *Cumulative*
 is the average spectrum since the start of the present UTC minute.
-(*Linear Avg* is not useful for JT9 or JT65; it is intended for use
+*Linear Avg* is useful in JT4 mode, especially when short-form
 messages are used.
 for JT9 or JT65; it is intended for use
 with the yet-to-be implemented JT4 mode.)
 - Four sliders control reference levels and scaling for waterfall
 colors and the spectrum plot.  Values around midscale are usually
 about right, depending on the input signal level, the chosen palette,
 and your own preferences.
 - *Smoothing* is active only when *Linear Average* has been selected.
 Smoothing the displayed spectrum over more than one bin can enhance
 your ability to detect weak EME signals with Doppler spread more than
 a few Hz.
--- a/doc/user_guide/coop-prgrms.adoc
+++ b/doc/user_guide/coop-prgrms.adoc
@ -1,5 +0,0 @@
 There is one program and one service that compliment _WSJT-X_ greatly. They are as follows:
 - {pskreporter}
 - {jtalert}
--- a/doc/user_guide/cooperating-programs.adoc
+++ b/doc/user_guide/cooperating-programs.adoc
@ -21,3 +21,8 @@ optional alert conditions (decoding of a new DXCC, new state, etc.),
 and convenient direct access to web services such as callsign lookup.
 image::images/jtalert.png[align="left",alt="JTAlert-X image"]
 * {alarmejt}, by F5JMH, is available only for Linux.  The program keeps
 its own logbook.  It fetches contact information from _WSJT_X and
 provides visual alerts for new DXCC entities and grid squares on the
 current band, as well as other options.
--- a/doc/user_guide/images/misc-controls-center.png
+++ b/doc/user_guide/images/misc-controls-center.png
--- a/doc/user_guide/images/wide-graph-controls.png
+++ b/doc/user_guide/images/wide-graph-controls.png
--- a/doc/user_guide/implementation.adoc
+++ b/doc/user_guide/implementation.adoc
@ -4,10 +4,9 @@
 Immediately before the start of a transmission _WSJT-X_ encodes a
 user's message and computes the sequence of tones to be sent.  The
 audio waveform is computed on-the-fly, with 16-bit integer samples
-sent to the audio output device at a 48000 Hz rate.  Generated JT65
+sent to the audio output device at a 48000 Hz rate.  Generated signals
-and JT9 signals have continuous phase and constant amplitude, and
+have continuous phase and constant amplitude, and there are no key
-there are no key clicks.  The transmitter's power amplifier need not
+clicks.  The transmitter's power amplifier need not be highly linear.
 be highly linear.
 .Receiving
@ -20,14 +19,14 @@ s, half the JT9 symbol length.
 .Decoding
 At the end of a reception sequence, about 50 seconds into the UTC
-minute, received data samples are forwarded to the decoder.  For
+minute, received data samples are forwarded to the decoder.  In JT9
-operator convenience the decoder goes through its full procedure
+and JT65 modes the decoder goes through its full procedure twice:
-twice: first at the selected Rx frequency, and then over the full
+first at the selected Rx frequency, and then over the full displayed
-displayed frequency range.  Each decoding pass can be described as a
+frequency range.  Each decoding pass can be described as a sequence of
-sequence of discrete blocks.  The functional blocks are different for
+discrete blocks.  Details of the functional blocks are different for
-the JT65 and JT9 modes.  In dual-mode JT9+JT65 operation on computers
+each mode.  In dual-mode JT9+JT65 operation on computers with more
-with more than one CPU, decoding computations for the two modes are
+than one CPU, decoding computations for the two modes are done in
-done in parallel.
+parallel.
 The basic decoding algorithm for JT65 mode is described in the 2005
 {jt65protocol} paper.  The following list summarizes the corresponding
--- a/doc/user_guide/install-mac.adoc
+++ b/doc/user_guide/install-mac.adoc
@ -6,7 +6,7 @@ installation notes.
 If you have already installed a previous version, you can retain it by
 changing its name in the *Applications* folder (say, from _WSJT-X_ to
-_WSJT-X_previous_).  You can then proceed to the installation phase.
+_WSJT-X_1.5_).  You can then proceed to the installation phase.
 Take note also of the following:
--- a/doc/user_guide/install-windows.adoc
+++ b/doc/user_guide/install-windows.adoc
@ -18,8 +18,9 @@ directory is ``invisible''.  It's there, however, and accessible.
 An alternative (shortcut) directory name is %LOCALAPPDATA%\WSJT-X\.
 - The built-in Windows facility for time synchronization is usually
-not adequate. We recommend the program _Meinberg NTP_: see {ntpsetup}
+not adequate. We recommend the program _Meinberg NTP_ (see {ntpsetup}
-for downloading and installation instructions.
+for downloading and installation instructions) or _Dimension 4_ from
 {dimension4}.
 - _WSJT-X_ expects your sound card to do its raw sampling at 48000 Hz.
 To ensure that this will be so when running under recent versions of
--- a/doc/user_guide/introduction.adoc
+++ b/doc/user_guide/introduction.adoc
@ -39,7 +39,7 @@ even if they are far below the audible threshold.
 _WSJT-X_ provides spectral displays for passbands up to 5 kHz,
 flexible rig control for nearly all modern radios used by amateurs,
-and a wide variety of special aids such as automatic Doppler control
+and a wide variety of special aids such as automatic Doppler tracking
 for EME QSOs and Echo testing.  The program runs equally well on
 Windows, Macintosh, and Linux systems, and installation packages are
 available for all three platforms.
--- a/doc/user_guide/jt65-jt9-differences.adoc
+++ b/doc/user_guide/jt65-jt9-differences.adoc
@ -1,41 +0,0 @@
 // Status=review
 The most striking difference between JT65 and JT9 is the much smaller
 occupied bandwidth of JT9: 15.6 Hz, compared with 177.6 Hz for JT65A.
 Transmissions in the two modes are essentially the same length, and
 both modes use exactly 72 bits to carry message information. At the
 user level the two modes support nearly identical message structures.
 JT65 signal reports are constrained to the range –1 to –30 dB. This
 range is more than adequate for EME purposes, but not really enough
 for optimum use at HF and below. S/N values displayed by the JT65
 decoder are clamped at an upper limit –1 dB, and in present JT65
 decoders the S/N scale is nonlinear above –10 dB.
 By comparison, JT9 allows for signal reports in the range –50 to +49
 dB. It manages this by taking over a small portion of ``message
 space'' that would otherwise be used for grid locators within 1 degree
 of the south pole. The S/N scale of the present JT9 decoder is
 reasonably linear (although it's not intended to be a precision
 measurement tool).  
 With clean signals and a clean noise background, JT65 achieves nearly
 100% decoding down to S/N = –22 dB and about 50% success at –24
 dB. JT9 is about 2 dB better, achieving 50% decoding at –26 dB. Both
 modes produce extremely low false-decode rates.
 Early experience suggests that under most HF propagation conditions
 the two modes have comparable reliability. The tone spacing of JT9 is
 about two-thirds that of JT65, so in some disturbed ionospheric
 conditions in the higher portion of the HF spectrum, JT65 may perform
 better.
 JT9 is an order of magnitude better in spectral efficiency. On a busy
 HF band, the conventional 2-kHz-wide JT65 sub-band is often filled
 with overlapping signals. Ten times as many JT9 signals can fit into
 the same frequency range, without collisions.
 JT65 signals often decode correctly even when they overlap. Such
 behavior is much less likely with JT9 signals, which fill their occupied
 bandwidth more densely. JT65 may also be more forgiving of small 
 frequency drifts.
--- a/doc/user_guide/jt65-protocol.adoc
+++ b/doc/user_guide/jt65-protocol.adoc
@ -1,51 +0,0 @@
 // Status=review
 JT65 was designed for making minimal QSOs via EME (``moon-bounce'') on
 the VHF and UHF bands. A detailed description of the protocol and its
 implementation in program _WSJT_ was published in {jt65protocol} for
 September-October, 2005. Briefly stated, JT65 uses 60 s T/R sequences
 and carefully structured messages. Standard messages are compressed so
 that two callsigns and a grid locator can be transmitted in just 71
 information bits.  A 72^nd^ bit serves as a flag to indicate that a
 message consists of arbitrary text (up to 13 characters) instead of
 callsigns and a grid locator.  Special formats allow other information
 such as add-on callsign prefixes (e.g., ZA/K1ABC) or numerical signal
 reports (in dB) to be substituted for the grid locator. The basic aim
 is to compress the most common messages used for minimally valid QSOs
 into a minimum fixed number of bits. After compression, a Reed Solomon
 (63,12) error-control code converts 72-bit user messages into
 sequences of 63 six-bit channel symbols.
 JT65 requires tight synchronization of time and frequency between
 transmitting and receiving stations. Each transmission is divided into
 126 contiguous time intervals or symbols of length 4096/11025 = 0.372
 s. Within each interval the waveform is a constant-amplitude sinusoid
 at one of 65 pre-defined frequencies. Frequency steps between
 intervals are accomplished in a phase-continuous manner. Half of the
 channel symbols are devoted to a pseudo-random synchronizing vector
 interleaved with the encoded information symbols. The sync vector
 allows calibration of time and frequency offsets between transmitter
 and receiver. A transmission nominally begins at t = 1 s after the
 start of a UTC minute and finishes at t = 47.8 seconds. The
 synchronizing tone is at 11025 × 472/4096 = 1270.46 Hz, and is normally
 sent in each interval having a “1” in the following pseudo-random
 sequence:
 100110001111110101000101100100011100111101101111000110101011001
 101010100100000011000000011010010110101010011001001000011111111
 Encoded user information is transmitted during the 63 intervals not
 used for the sync tone. Each channel symbol generates a tone at
 frequency 11025 × 472/4096 + 11025/4096 × (N+2) × m, where N is the
 value of the six-bit symbol, 0 ≤ N ≤ 63, and m is 1, 2, or 4 for JT65
 sub-modes A, B, or C.  Sub-mode JT65A is always used at HF.
 For EME (but, conventionally, not on the HF bands) the signal report
 OOO is sometimes used instead of numerical signal reports. It is
 conveyed by reversing sync and data positions in the transmitted
 sequence.  Shorthand messages for RO, RRR, and 73 dispense with the
 sync vector entirely and use time intervals of 16384/11025 = 1.486 s
 for pairs of alternating tones. The lower frequency is always 1270.46
 Hz, the same as that of the sync tone, and the frequency separation is
 110250/4096 = 26.92 Hz multiplied by n × m, with n = 2, 3, 4 for the
 messages RO, RRR, and 73.
--- a/doc/user_guide/jt9-protocol.adoc
+++ b/doc/user_guide/jt9-protocol.adoc
@ -1,20 +0,0 @@
 // Status=review
 //Needs work!
 JT9 is designed for making minimally valid QSOs at LF, MF, and HF. It
 uses 72-bit structured messages nearly identical (at the user level)
 to those in JT65. Error control coding (ECC) uses a strong
 convolutional code with constraint length K=32, rate r=1/2, and a zero
 tail, leading to an encoded message length of (72+31) × 2 = 206
 information-carrying bits. Modulation is nine-tone frequency-shift
 keying, 9-FSK.  Eight tones are used for data, one for
 synchronization. Eight data tones means that three data bits are
 conveyed by each transmitted information symbol. Sixteen symbol
 intervals are devoted to synchronization, so a transmission requires a
 total of 206 / 3 + 16 = 85 (rounded up) channel symbols. The sync
 symbols are those numbered 1, 2, 5, 10, 16, 23, 33, 35, 51, 52, 55,
 60, 66, 73, 83, and 85 in the transmitted sequence.  Each symbol lasts
 for 6912 sample intervals at 12000 samples per second, or about 0.576
 seconds. Tone spacing of the 9-FSK modulation is 12000/6912 = 1.736
 Hz, the inverse of the symbol duration. The total occupied bandwidth
 is 9 × 1.736 = 15.6 Hz.
--- a/doc/user_guide/logging.adoc
+++ b/doc/user_guide/logging.adoc
@ -22,10 +22,10 @@ before'' status for this callsign (according to log file
 background color, as follows:
 [horizontal]
-!::  (default color bright purple) -- New DXCC entity
+!::  default color bright purple: -- New DXCC entity
-~::  (light pink) -- You have already worked this DXCC entity but not 
+~::  light pink: -- You have already worked this DXCC entity but not 
 this station
- ::  (green) -- You have previously worked the calling station
+ ::  green: -- You have previously worked the calling station
 In this respect the program does not distinguish between modes, but it
 does differentiate between bands.
--- a/doc/user_guide/make-qso.adoc
+++ b/doc/user_guide/make-qso.adoc
@ -7,16 +7,12 @@ minimal QSOs using short, structured messages. The process works best
 if you use these formats and follow standard operating practices. The
 recommended basic QSO goes something like this:
-[width="90%",cols="3,7,12",options="header"]
+ CQ K1ABC FN42                          #K1ABC calls CQ
-|=======================================
+                   K1ABC G0XYZ IO91     #G0XYZ answers
-|UTC|Transmitted Message|Comment
+ G0XYZ K1ABC –19                        #K1ABC sends report
-|0001|CQ K1ABC FN42|K1ABC calls CQ
+                   K1ABC G0XYZ R–22     #G0XYZ sends R+report
-|0002|K1ABC G0XYZ IO91|G0XYZ answers
+ G0XYZ K1ABC RRR                        #K1ABC sends RRR
-|0003|G0XYZ K1ABC –19|K1ABC sends report
+                   K1ABC G0XYZ 73       #G0XYZ sends 73
 |0004|K1ABC G0XYZ R–22|G0XYZ sends acknowledgment and report
 |0005|G0XYZ K1ABC RRR|K1ABC sends acknowledgment
 |0006|K1ABC G0XYZ 73|G0XYZ sends 73
 |=======================================
 *Standard messages* consist of two callsigns (or CQ, QRZ, or DE and
 one callsign) followed by the transmitting station’s grid locator, a
@ -35,9 +31,10 @@ lie in the range –30 to –1 dB, and values are significantly compressed
 above about -10 dB.  JT9 supports the extended range –50 to +49 dB and
 assigns more reliable numbers to relatively strong signals.
-IMPORTANT: Signals become visible on the waterfall around S/N = –26 dB and
+IMPORTANT: Signals become visible on the waterfall around S/N = –26 dB
-audible (to someone with very good hearing) around –15 dB. Thresholds
+and audible (to someone with very good hearing) around –15
-for decodability are around –24 dB for JT65, –26 dB for JT9.
+dB. Thresholds for decodability are around -23 dB for JT4, –24 dB for
 JT65, –26 dB for JT9.
 === Free Text Messages
@ -46,7 +43,7 @@ Free-format messages such as ``TNX ROBERT 73'' or ``5W VERT 73 GL''
 are supported, up to a maximum of 13 characters, including spaces.  In
 general you should avoid the character / in free-text messages, as the
 program may then try to interpret your construction as part of a
-compound callsign.  It should be obvious that the JT9 and JT65
+compound callsign.  It should be obvious that the JT4, JT9, and JT65
 protocols are not designed or well suited for extensive conversations
 or rag-chewing.
@ -73,8 +70,8 @@ compound callsigns:
 The following messages are _not_ valid, because a third word is not
 permitted in any message containing a *Type 1* compound callsign:
- ZA/K1ABC G0XYZ -22        #These messages will be sent
+ ZA/K1ABC G0XYZ -22        #These messages are invalid; each would 
- G0XYZ K1ABC/4 73          #without the third "word"
+ G0XYZ K1ABC/4 73          # be sent without its third "word"
 A QSO between two stations using *Type 1* compound-callsign messages
 might look like this:
@ -108,8 +105,8 @@ messages containing *Type 2* compound callsigns:
 DE W4/G0XYZ RRR
 DE W4/G0XYZ 73
-In each case, the message is treated as *Type 2* because the add-on
+In each case, the compound callsign is treated as *Type 2* because the
-prefix or suffix is _not_ one of those in the fixed list.  Note
+add-on prefix or suffix is _not_ one of those in the fixed list.  Note
 that a second callsign is never permissible in these messages.
 IMPORTANT: Remember that during a transmission your transmitted message is
@ -162,5 +159,6 @@ as the following checklist:
 - Radio filters centered and set to widest available passband (up to 5 kHz).
-IMPORTANT: Remember that JT9 and J65 generally do not require high
+IMPORTANT: Remember that JT4, JT9, J65, and WSPR generally do not
-power. Under most HF propagation conditions, QRP is the norm.
+require high power. Under most HF propagation conditions, QRP is the
 norm.
--- a/doc/user_guide/new_features.adoc
+++ b/doc/user_guide/new_features.adoc
@ -19,25 +19,26 @@ be always on-frequency to within about 1 Hz.
 - Mode-specific standard working frequencies accessible from the
 drop-down band selector.
- A number of corrections have been made to the Hamlib library, thereby
+- A number of corrections to the Hamlib library, fixing balky
-fixing balky rig-control features.  A few unreliable features peculiar
+rig-control features.  A few unreliable features peculiar to
-to particular radios have been removed.
+particular radios have been removed.
- 
+
 === Future releases
 Much work has already been done on Version 1.7 of _WSJT-X_.  (Up to
-now it has been called v1.6.1.)  More than 100 people have been
+now this branch has been called v1.6.1.)  More than 100 people have
-building this version for themselves, as development progresses, and
+been building this version for themselves, as development progresses,
-reporting on their experiences.  The next release will likely have the
+and reporting on their experiences.  The next release will likely have
-following features not present in Version 1.6.0, and perhaps others as
+the following features not present in Version 1.6.0, and perhaps
-well:
+others as well:
 - *JTMSK* mode, intended for meteor scatter, ionospheric scatter,
 aircraft scatter, and the like.  Unlike the FSK441, ISCAT, and JTMS
-modes present in the older program _WSJT_, *JTMSK* uses strong forward
+modes present in the older program _WSJT_, *JTMSK* uses forward error
-error correction and structured messages identical to those in JT4,
+correction and structured messages identical to those in JT4, JT9, and
-JT9, and JT65.
+JT65.
 - A significantly improved decoder for JT65, especially advantageous
 when used in crowded HF bands.  Starting with Version 1.7, _WSJT-X_
-will longer use the patented, closed-source Koetter-Vardy algorithm.
+will no longer use the patented, closed-source Koetter-Vardy
 algorithm.
--- a/doc/user_guide/protocols.adoc
+++ b/doc/user_guide/protocols.adoc
@ -0,0 +1,137 @@
 [[JT65PRO]]
 === JT65
 JT65 was designed for making minimal QSOs via EME (``moon-bounce'') on
 the VHF and UHF bands. A detailed description of the protocol and its
 implementation in program _WSJT_ was published in {jt65protocol} for
 September-October, 2005. Briefly stated, JT65 uses 60 s T/R sequences
 and carefully structured messages. Standard messages are compressed so
 that two callsigns and a grid locator can be transmitted in just 71
 information bits.  A 72^nd^ bit serves as a flag to indicate that a
 message consists of arbitrary text (up to 13 characters) instead of
 callsigns and a grid locator.  Special formats allow other information
 such as add-on callsign prefixes (e.g., ZA/K1ABC) or numerical signal
 reports (in dB) to be substituted for the grid locator. The basic aim
 is to compress the most common messages used for minimally valid QSOs
 into a minimum fixed number of bits. After compression, a Reed Solomon
 (63,12) error-control code converts 72-bit user messages into
 sequences of 63 six-bit channel symbols.
 JT65 requires tight synchronization of time and frequency between
 transmitting and receiving stations. Each transmission is divided into
 126 contiguous tone intervals or ``symbols'' of length 4096/11025 =
 0.372 s. Within each interval the waveform is a constant-amplitude
 sinusoid at one of 65 pre-defined frequencies. Frequency steps between
 intervals are accomplished in a phase-continuous manner. Half of the
 channel symbols are devoted to a pseudo-random synchronizing vector
 interleaved with the encoded information symbols. The sync vector
 allows calibration of time and frequency offsets between transmitter
 and receiver. A transmission nominally begins at t = 1 s after the
 start of a UTC minute and finishes at t = 47.8 seconds. The
 synchronizing tone is at 11025 × 472/4096 = 1270.46 Hz, and is
 normally sent in each interval having a “1” in the following
 pseudo-random sequence:
 100110001111110101000101100100011100111101101111000110101011001
 101010100100000011000000011010010110101010011001001000011111111
 Encoded user information is transmitted during the 63 intervals not
 used for the sync tone. Each channel symbol generates a tone at
 frequency 11025 × 472/4096 + 11025/4096 × (N+2) × m, where N is the
 value of the six-bit symbol, 0 ≤ N ≤ 63, and m is 1, 2, or 4 for JT65
 sub-modes A, B, or C.  Sub-mode JT65A is always used at HF.
 For EME (but, conventionally, not on the HF bands) the signal report
 OOO is sometimes used instead of numerical signal reports. It is
 conveyed by reversing sync and data positions in the transmitted
 sequence.  Shorthand messages for RO, RRR, and 73 dispense with the
 sync vector entirely and use time intervals of 16384/11025 = 1.486 s
 for pairs of alternating tones. The lower frequency is always 1270.46
 Hz, the same as that of the sync tone, and the frequency separation is
 110250/4096 = 26.92 Hz multiplied by n × m, with n = 2, 3, 4 for the
 messages RO, RRR, and 73.
 [[JT4PRO]]
 === JT4
 JT4 uses 72-bit structured messages nearly identical to those in
 JT65. Error control coding (ECC) uses a strong convolutional code with
 constraint length K=32, rate r=1/2, and a zero tail, leading to an
 encoded message length of (72+31) x 2 = 206 information-carrying
 bits. Modulation is 4-tone frequency-shift keying at 11025 / 2520 =
 4.375 baud.  Each symbol carries one information bit (the most
 significant bit) and ony synchronizing bit (the least signicifant
 bit).  The pseudo-random sync vector is the following sequence:
 000011000110110010100000001100000000000010110110101111101000
 100100111110001010001111011001000110101010101111101010110101
 011100101101111000011011000111011101110010001101100100011111
 10011000011000101101111010
 [[JT9PRO]]
 === JT9
 JT9 is designed for making minimally valid QSOs at LF, MF, and HF. It
 uses 72-bit structured messages nearly identical (at the user level)
 to those in JT65. Error control coding (ECC) uses a strong
 convolutional code with constraint length K=32, rate r=1/2, and a zero
 tail, leading to an encoded message length of (72+31) × 2 = 206
 information-carrying bits. Modulation is nine-tone frequency-shift
 keying, 9-FSK.  Eight tones are used for data, one for
 synchronization. Eight data tones means that three data bits are
 conveyed by each transmitted information symbol. Sixteen symbol
 intervals are devoted to synchronization, so a transmission requires a
 total of 206 / 3 + 16 = 85 (rounded up) channel symbols. The sync
 symbols are those numbered 1, 2, 5, 10, 16, 23, 33, 35, 51, 52, 55,
 60, 66, 73, 83, and 85 in the transmitted sequence.  Each symbol lasts
 for 6912 sample intervals at 12000 samples per second, or about 0.576
 seconds. Tone spacing of the 9-FSK modulation is 12000/6912 = 1.736
 Hz, the inverse of the symbol duration. The total occupied bandwidth
 is 9 × 1.736 = 15.6 Hz.
 [[PROTOCOL_SUMMARY]]
 === Summary
 Frequency spacing between tones, total occupied bandwidth, and
 approximate decoding thresholds are given for the various submodes of
 JT4, JT9, and JT65 in the following table:
 Submode Spacing   BW    S/N
           (Hz)   (Hz)    dB
 ----------------------------
 JT4A     4.375   17.5   -23
 JT4B     8.75    35.0   -22
 JT4C    17.5     70.0   -21
 JT4D    39.375  157.5   -20
 JT4E    78.75   315.0   -19
 JT4F    157.5   630.0   -18
 JT4G    315.0  1260.0   -17
 JT9    1.7361  15.625   -27
 JT65A  2.6917   177.6   -25
 JT65B  5.3833   355.3   -24
 JT65C  10.767   710.6   -23
 Transmissions in all three modes are essentially the same length, and
 all use 72 bits to carry message information. At user level the modes
 support nearly identical message structures.
 JT4 and JT65 signal reports are constrained to the range –1 to –30
 dB. This range is more than adequate for EME purposes, but not enough
 for optimum use at HF. S/N values displayed by the JT4 and JT65
 decoders are clamped at an upper limit –1 dB, and the S/N scale is
 nonlinear above –10 dB.
 By comparison, JT9 allows for signal reports in the range –50 to +49
 dB. It manages this by taking over a small portion of ``message
 space'' that would otherwise be used for grid locators within 1 degree
 of the south pole. The S/N scale of the present JT9 decoder is
 reasonably linear (although it's not intended to be a precision
 measurement tool).  
 JT9 is an order of magnitude better than JT65 in spectral
 efficiency. On a busy HF band, the conventional 2-kHz-wide JT65
 sub-band is often filled with overlapping signals. Ten times as many
 JT9 signals can fit into the same frequency range, without collisions.
--- a/doc/user_guide/settings-audio.adoc
+++ b/doc/user_guide/settings-audio.adoc
@ -11,8 +11,8 @@ IMPORTANT: If you select the audio output device that is also your
 computer's default audio device, be sure to turn off all system sounds
 to prevent transmitting them over the air.
-IMPORTANT: If necessary, be sure that your audio device in configured to
+IMPORTANT: Be sure that your audio device in configured to sample at
-sample at 48000 Hz, 16 bits.
+48000 Hz, 16 bits.
 - _Save Directory_: _WSJT-X_ can save its received audio sequences as
 +.wav+ files.  A default directory for these files is provided; you
--- a/doc/user_guide/settings-frequencies.adoc
+++ b/doc/user_guide/settings-frequencies.adoc
@ -3,7 +3,7 @@
 [[FIG_BAND_SETTINGS]]
 image::images/settings-frequencies.png[align="center",alt="Frequency Screen"]
-_Working Frequencies_: By default the *Working Frequency* table
+_Working Frequencies_: By default the *Working Frequencies* table
 contains a list of currently recommended dial frequencies for each
 mode.  You can modify the frequency table as desired.
@ -23,22 +23,22 @@ configuration.
 _Frequency Calibration_: If you have calibrated your radio using WWV
 or other reliable frequency references, or perhaps with the technique
-described {fmt_wspr}, enter the measured values for Intercept A and
+described {fmt_wspr}, enter the measured values for _Intercept_ A and
-Slope B in the equation
+_Slope_ B in the equation
- Dial error = A * B*f
+ Dial error = A + B*f
 where ``Dial error'' and A are in Hz, f is frequency in MHz, and B is
-parts per million (ppm).
+in parts per million (ppm).
 Frequency values sent to the radio and received from it will
 then be adjusted accordingly so that frequencies displayed by _WSJT-X_
-are correct.
+are accurate.
 _Station Information_: You can save *Band*, *Offset* and *Antenna
 Description* information for your station.  The antenna information
 will be included in reception reports sent to {pskreporter}.  By
-default the frequency *Offset* for each band is zero.  Nonzero offsets
+default the frequency offset for each band is zero.  Nonzero offsets
 may be added if (for example) a transverter is in use.
 - For a simple setup approach you might want to delete any unwanted
@ -47,7 +47,7 @@ on a *Frequency* entry and type *Ctrl+A* to ``select all,'' and
 drag-and-drop the entries onto the _Station Information_ table.  You
 can then add any transverter offsets and antenna details.
- To avoid typing the same information multiple times, you can
+- To avoid typing the same information many times, you can
 drag-and-drop entries between the lines of the _Station Information_
 table.
--- a/doc/user_guide/settings-radio.adoc
+++ b/doc/user_guide/settings-radio.adoc
@ -38,7 +38,8 @@ for the proper parameter values.
 * _Force Control Lines_: A few station setups require the CAT serial
 port’s *RTS* and/or *DTR* control lines to be forced high or
-low. Check these boxes only if you are sure they are needed.
+low. Check these boxes only if you are sure they are needed (for
 example, to power the radio serial interface).
 - _PTT Method_: select *VOX*, *CAT*, *DTR*, or *RTS* as the desired
 method for T/R switching.  If your choice is *DTR* or *RTS*, select
--- a/doc/user_guide/settings-txmacros.adoc
+++ b/doc/user_guide/settings-txmacros.adoc
@ -4,7 +4,7 @@
 image::images/tx-macros.png[align="center",alt="Tx Macros Screen"]
 *Tx Macros* are an aid for sending brief, frequently used free-text
- messages.
+messages such as the examples shown above.
 - To add a new message to the list, enter the desired text (up to 13
 characters) in the entry field at top, then click *Add*.
--- a/doc/user_guide/support.adoc
+++ b/doc/user_guide/support.adoc
@ -1,4 +1,4 @@
-=== Setup Help
+=== Help with Setup
 The best source of help in setting up your station or configuring
 _WSJT-X_ is the {wsjt_yahoo_group} at email address
--- a/doc/user_guide/transceiver-setup.adoc
+++ b/doc/user_guide/transceiver-setup.adoc
@ -21,9 +21,9 @@ mode, you should normally choose the widest one possible, up to about
 5 kHz.  This choice has the desirable effect of allowing the *Wide
 Graph* (waterfall and 2D spectrum) to display the conventional JT65
 and JT9 sub-bands simultaneously on most HF bands.  Further details
-are provided in the <<TUTORIAL,Tutorial>> section.  A wider displayed
+are provided in the <<TUTORIAL,Basic Operating Tutorial>>.  A wider
-bandwidth may also be helpful at VHF and above, where usage of JT65
+displayed bandwidth may also be helpful at VHF and above, where JT4
-and JT4 is found over a much wider range of frequencies.
+and JT65 signals are found over much wider ranges of frequencies.
 - If you have only a standard SSB filter you won’t be able to display
 more than about 2.7 kHz bandwidth.  Depending on the exact dial
@ -58,6 +58,6 @@ digital slider labeled *Pwr* at the right edge of the main window.
 IMPORTANT: Windows Vista and later incorrectly configure audio devices
 using the Texas Instruments PCM2900 series CODEC for microphone input
 rather line input.  (This chip is used in many radios with built-in
-USB CODECs, as well as various other audio interfaces.)  If using such
+USB CODECs, as well as various other audio interfaces.)  If you are
-a device, be sure to set the mic level in the Recording Device
+using such a device, be sure to set the mic level in the Recording
-Properties to 0 dB.
+Device Properties to 0 dB.
--- a/doc/user_guide/tutorial-example1.adoc
+++ b/doc/user_guide/tutorial-example1.adoc
@ -16,13 +16,14 @@ image::images/main-ui-1.6.png[align="center",alt="Main UI and Wide Graph"]
 .Decoding Overview
-Decoding takes place at the end of a receive sequence and is proceeds
+Decoding takes place at the end of a receive sequence and proceeds in
-in two steps.  The first decode takes place at the selected Rx
+two steps.  The first decode is done at the selected Rx frequency,
-frequency, indicated by the U-shaped green marker on the waterfall
+indicated by the U-shaped green marker on the waterfall scale.
-scale.  Results appear in both the left (*Band Activity*) and right
+Results appear in both the left (*Band Activity*) and right (*Rx
-(*Rx Frequency*) text windows on the main screen. The program then
+Frequency*) text windows on the main screen. The program then finds
-finds and decodes all signals in the selected mode over the displayed
+and decodes all signals in the selected mode over the displayed
-frequency range. The red marker indicates your Tx frequency.
+frequency range. The red marker on the waterfall scale indicates your
 Tx frequency.
 Seven JT9 signals are present in the example file, all decodable.
 When this file was recorded KF4RWA was finishing a QSO with K1JT.
@ -80,7 +81,8 @@ automatically generated and selected for your next transmission.
 (Alternatively, you might choose to send a free text message or to
 call CQ again.)
- Click somewhere on the waterfall to set Rx frequency (green marker).
+- Click somewhere on the waterfall to set Rx frequency (green marker
 on waterfall scale).
 - Ctrl-click on the waterfall to set both Rx and Tx frequencies.
--- a/doc/user_guide/tutorial-example2.adoc
+++ b/doc/user_guide/tutorial-example2.adoc
@ -38,8 +38,8 @@ for JT9 and JT65 modes run simultaneously, so their results will be
 interspersed.  The *Band Activity* window contains all decodes (you
 might need to scroll back in the window to see some of them).  A
 signal at the frequency specified by the green marker is given
-decoding priority, and its message is displayed in the *Rx Frequency*
+decoding priority, and its message is displayed also in the *Rx
-window.
+Frequency* window.
 [[FigDecodes]]
 image::images/decodes.png[align="center"]
@ -102,16 +102,16 @@ The signals in this file are all JT9 signals.  To decode them
 automatically in *JT9+JT65* mode you’ll need to move the *JT65 nnnn JT9*
 delimiter down to 1000 Hz or less.
-.Start, Zero, and Gain
+.Waterfall Controls
-Now is a good time to experiment with the *Start*, *Zero*, and *Gain*
+Now is a good time to experiment with the *Start* control and the
-parameters.  *Start* determines the frequency displayed at the left
+sliders controlling gain and zero-point of the waterfall and spectrum
-side of the waterfall scale.  *Zero* sets the baseline level for
+plots.  *Start* determines the frequency displayed at the left side of
-colors, and *Gain* sets the sensitivity for color changes.  For the
+the waterfall scale.  Sliders set the baseline level and gain for the
-receiver setup of this file good values are close to *Zero*=0,
+waterfall and the several types of spectra.  Good starting values
-*Gain*=0.  You may want to uncheck *Flatten* when adjusting the *Zero*
+should be close to mid-scale.  You might want to uncheck *Flatten*
-and *Gain* controls.  Re-open the wave file after each change, to see
+when adjusting the sliders.  Re-open the wave file after each change,
-the new results.
+to see the new results.
 IMPORTANT: When finished with this Tutorial, don’t forget to re-enter
 your own callsign as *My Call* on the *Settings | General* tab.
--- a/doc/user_guide/tutorial-main-window.adoc
+++ b/doc/user_guide/tutorial-main-window.adoc
@ -4,13 +4,13 @@
 - Select *JT9* from the *Mode* menu and *Deep* from the *Decode* menu.
- Set the audio frequencies to *Tx 1224 Hz* and *Rx 1224 Hz*.  You
+- Set the audio frequencies to *Tx 1224 Hz* and *Rx 1224 Hz*.  
-can type numbers directly into these controls, as well as using their 
+
-up/down arrows.
+IMPORTANT: Sliders and spinner controls respond to *Arrow* key presses
 and *Page Up/Down* key presses, with the *Page* keys moving the
 controls in larger steps.  You can also type numbers directly into
 the spinner controls.
 - Select *Tab 2* (below the *Decode* button) to choose the alternative
 set of controls for generating and selecting Tx messages.
 IMPORTANT: Sliders and spin-box controls respond to arrow key presses
 and Page Up/Down key presses, with the Page keys moving the controls
 in larger steps.
--- a/doc/user_guide/vhf-features.adoc
+++ b/doc/user_guide/vhf-features.adoc
@ -57,8 +57,7 @@ one-way shift is +3096.5 Hz.  Therefore, the receive frequency is set
 to 10,360.103097 Hz.  When a transmission is started, the frequency
 is reset to 3096.5 Hz below the nominal frequency.
-
+- Spinner controls at top right of the *Astronomical Data* window let you
 - Spinner controls at top right of the Astronomical Data window let you
 set a working frequency above the nominal band edge. The frequency above
 band edge is the sum of the numbers in these two controls (kHz + Hz).
@ -74,7 +73,7 @@ the 10 GHz band.
 - If using a transverter, set the appropriate offset on the *Settings
 | Frequencies* tab.  Offset is defined as (desired transceiver dial
 reading) minus (desired on-the-air frequency).  For example, when
-using a 144 MHz radio at 10368 MHz, offset = (144 - 10368) =
+using a 144 MHz radio at 10368 MHz, _Offset (MHz)_ = (144 - 10368) =
 -10224.000.  If the band is already in the table, you can edit the
 offset by double clicking on the offset field itself.  Otherwise a new
 band can be added by right clicking in the table and selecting _Insert_.
@ -83,10 +82,11 @@ image::images/Add_station_info.png[align="center",alt="Station information"]
 - The JT4 decoder in _WSJT-X_ includes optional facilities for
 averaging over successive transmissions and also correlation decoding,
-sometimes known as ``Deep Search''.  The *Decode* menu appears to
+sometimes known as ``Deep Search''.  
-provide options to set different decoding behavior.  However, in JT4 mode
+
-this program version always behaves as if you have selected _Include
+IMPORTANT: The *Decode* menu appears to provide options to set
-correlation_.
+different decoding behavior.  However, in JT4 mode _WSJT-X_ Version
 1.6 always behaves as if you have selected _Include correlation_.
 image::images/decoding_depth.png[align="center",alt="Decoding Depth"]
@ -94,9 +94,8 @@ image::images/decoding_depth.png[align="center",alt="Decoding Depth"]
 activate automatic generation of these messages, check the box labeled
 _Sh_ on the main window.
-IMPORTANT: Many additional hints for using JT4 and Echo mode on the
+IMPORTANT: Thanks to G3WDG, many additional hints for using JT4 and
-EME path are available {jt4eme}.  (Thanks to G3WDG for preparing this 
+Echo mode on the EME path are available {jt4eme}.
 useful document.)
 === Echo Mode
--- a/doc/user_guide/wsjtx-main.adoc
+++ b/doc/user_guide/wsjtx-main.adoc
@ -102,11 +102,14 @@ include::transceiver-setup.adoc[]
 [[TUTORIAL]]
 == Basic Operating Tutorial
-Sections <<TUT_MAIN,7.1>> through <<TUT_EX2,7.4>> cover basic
+<<TUT_MAIN,Sections 6.1>> through <<TUT_EX2,6.4>> cover basic
 operation for making two-way QSOs with modes JT9 and JT65 on the HF
-bands.  Section <<TUT_WSPR,7.5>> covers WSPR mode.  If you are a new user
+bands.  <<WSPR,Section 7>> covers WSPR mode, and 
-of _WSJT-X_ we suggest that you go through the full tutorial.  It should
+<<VHF_AND_UP,Section 8>> covers VHF+ features.  If you are a new 
-take no more than 20 minutes.
+user of _WSJT-X_ we suggest that you go through the full HF-oriented 
 tutorial while at your radio.  It should take no more than 20 minutes.
 If your main interests are WSPR of VHF+, you may then proceed to 
 Sections 7 and 8.
 [[TUT_MAIN]]
 === Main Window Settings
@ -187,18 +190,8 @@ include::faq.adoc[]
 [[PROTOCOLS]]
 == Protocol Specifications
 include::protocols.adoc[]
 [[JT65PRO]]
 === JT65
 include::jt65-protocol.adoc[]
 [[JT9PRO]]
 === JT9
 include::jt9-protocol.adoc[]
 [[JT65_JT9]]
 === JT65 & JT9 Differences
 include::jt65-jt9-differences.adoc[]
 [[TXRX]]
 == Implementation Details