WSJT-X/doc/user_guide/jt65-jt9-differences.adoc
Bill Somerville c197d216b3 First attempt at adding the WSJT-X user guide to the CMake build
These documentation source files are not  the one true version, just a
copy for testing purposes. DO NOT EDIT THESE FILES.

To use this  on Windows you will need a  working asciidoc installation
and  the  path  to  it  must be  included  in  your  CMAKE_PREFIX_PATH
(probably via a  local CMake tool chain file). At  the time of writing
the official  asciidoc package does  not work on Windows.   The latest
development  master does  however  work,  it can  be  downloaded as  a
snapshot ZIP archive from here:

  https://github.com/asciidoc/asciidoc/archive/master.zip

git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5316 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-04-28 18:37:50 +00:00

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// 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. Moreover, the S/N scale
in present JT65 decoders 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 its not intended to be a precision
measurement tool).
With clean signals and a clean nose background, JT65 achieves nearly
100% decoding down to S/N = 22 dB and about 50% at 24 dB. JT9 is
about 2 dB better, achieving 50% decoding at about 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.